Dynamic Computer Systems and Uses Thereof

ABSTRACT

The invention concerns computer systems that are specially adapted to propagate content over a dynamic network, substantially in real time, by virtue of the locational proximity of interconnected network-joined Client Computers, at least one of which communicates with an interconnected Client Computer via infrared signal, laser pulse, or radio frequency. Preferably, the content will also be weighted (for example, proximity-weighted, rank-weighted, topic-weighted, query-weighted, time-weighted, location-weighted, locality-weighted, vote-weighted, segment-weighted, geophysically-weighted, etc.). The invention particularly concerns such computer systems that employ more than one such weighting. The invention particularly concerns such computer systems that operate using, or through, mobile devices, particularly for distributed computing applications, including social media applications and communications applications conducted over Restricted Computer Networks. The invention particularly concerns such computer systems that comprise an interconnected Client Computer that is mounted in a vehicle, installed on or in a structure or is a component of a drone device.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a continuation-in-part of U.S. patent application Ser. No. 15/667,385 (pending), which was filed on Aug. 2, 2017, which application is a continuation-in-part of U.S. patent application Ser. No. 14/512,442, which was filed on Oct. 12, 2014 (and which issued on Aug. 22, 2017, as U.S. Pat. No. 9,742,853), and which claims priority to U.S. Patent Application No. 62/000,015 (filed on May 19, 2014; now expired), each of which applications is hereby incorporated by reference in its entirety.

BACKGROUND OF THE INVENTION Field of the Invention

The invention concerns computer systems that are specially adapted to propagate content over a dynamic network, substantially in real time, by virtue of the locational proximity of interconnected network-joined Client Computers, at least one of which communicates with an interconnected Client Computer via infrared signal, laser pulse, or radio frequency. Preferably, the content will also be weighted (for example, proximity-weighted, rank-weighted, topic-weighted, query-weighted, time-weighted, location-weighted, locality-weighted, vote-weighted, segment-weighted, geophysically-weighted, etc.). The invention particularly concerns such computer systems that employ more than one such weighting. The invention particularly concerns such computer systems that operate using, or through, mobile devices, particularly for distributed computing applications, including social media applications and communications applications conducted over Restricted Computer Networks. The invention particularly concerns such computer systems that comprise an interconnected Client Computer that is mounted in a vehicle, installed on or in a structure or is a component of a drone device.

Description of Related Art

Online social media services, such as social networking sites, search engines, news aggregators, blogs, and the like provide a rich environment for users to comment on events of interest and communicate with other users. Examples of social media services include: 43 Things®, Academia.edu®, Bebo®, Blauk, Blogster, Bolt.com, Buzznet®, CafeMom®, Care2®, CaringBridge®, Classmates.com®, CouchSurfing®, Diaspora*®, Eons.com, Experience Project, Exploroo, Facebook®, Faceparty®, Face.com®, Flixster®, Flickr®, Focus.com, Foursquare®, Friendica, Friends Reunited, Google+®, GovLoop®, Instagram®, Jaiku®, Lifeknot®, LinkedIn®, MEETin, Meetup®, MocoSpace®, MyHeritage®, MyLife®, My Opera®, Myspace®, Pinterest®, Plaxo®, Reddit®, ReverbNation.com, SocialVibe®, Spaces, SnapChat®, Stage 32®, Stickam®, Talkbiznow, TravBuddy.com, Travellerspoint, tribe.net, Tumblr®, Twitter®, Vimeo®, WhatsApp®, Yammer®, and Yelp®.

Proximity analysis in social networking has been used in advertising and marketing, for example to permit merchants to more efficiently market their products and services to users (see, e.g., U.S. Pat. No. 8,306,921 and United States Patent Publications No. 2009/0157473; 2009/0204600; 2011/0196801; 2012/0084807; 2012/0084811 and 2012/0136723 and PCT Publications No. WO 2011/097510 and WO 2013/052081). Conversely, methods of sharing multimedia have been developed that measure the distance (“hop”) between sending and receiving computers so as to provide a measure of the level of interest in such by the members of the social network (with multimedia having greater hop-distance being indicative of a higher level of interest) (see, e.g., U.S. Pat. No. 8,260,882 and United States Patent Publication No. 2009/0157845). Proximity analysis has been proposed as a means for providing enhanced security surveillance (see, e.g., United States Patent Publications No. 2009/0292549 and 2010/0036875). Methods of information sharing associated with an event location are disclosed in U.S. Pat. Nos. 8,204,759 and 8,510,383 and in United States Patent Publications No. 2011/0066743 and 2011/0131144. Social networks in which participants seek help or the performance of other in the user's vicinity are described in United States Patent Publications No 2011/0238763 and 2011/0282793.

Content recommendation systems allowing users to identify friends, or recommend content or activities to friends, in their present or planned future geographic locations have been described (see, e.g., U.S. Pat. No. 8,108,414 and United States Patent Publication No. 2011/0288912; 2012/0124059; 2013/0218967; 2013/0267251 and 2014/0047357; and PCT Publication No. WO 2013/126293).

Examples of computer system architecture for social networks or for location determination are described in U.S. Pat. Nos. 7,818,394; 7,831,684; 7,844,671; 7,949,611; 8,073,807; 8,108,414; 8,219,500; 8,224,727; 8,266,145; 8,311,289; 8,341,162; 8,407,282; 8,473,386; 8,473,500; 8,489,516; 8,495,095; 8,504,507; 8,521,180; 8,554,868; 8,566,605; 8,601,378; 8,607,146; 8,612,869 and 8,620,828 and in United States Patent Publications No. 2014/0052544; 2014/0052795 and US 2013/0073473 and in European Patent Publication EP 2151793 and in PCT Publications No. WO 2013/154679; WO 2013/170082; WO 2013/181662; WO 2013/184407 and WO 2013/184957. In particular, such computer system architecture may have a server-centered architecture (e.g., U.S. Pat. Nos. 8,676,667; 8,695,077; 8,694,579; 8,693,982; 8,693,464; 8,683,565; 8,670,414; 8,677,418; 8,676,934; 8,667,081; 8,662,386; 8,656,421; 8,647,207; 8,635,499; 8,630,867; 8,599,848; 8,601,265; 8,606,930; 8,615,010; 8,612,646; 8,619,822; 8,583,781; 8,577,954; 8,582,727; 8,560,939; 8,571,526; etc.) or a peer-to-peer architecture (e.g., U.S. Pat. Nos. 8,694,587; 8,693,484; 8,693,431; 8,693,392; 8,693,391; 8,690,050; 8,689,307; 8,688,803; 8,688,801; 8,688,789; 8,688,780; 8,688,779; 8,688,111; 8,688,038; 8,687,536; 8,683,551; 8,682,495; 8,677,017; 8,676,925; 8,676,882; 8,676,855; 8,676,165; 8,671,208; 8,671,202; 8,671,188; etc.).

Methods of searching, sorting and grouping data and of displaying data on computers and mobile devices in response to user-defined criteria have also been described (see, e.g., European Patent Publications No. EP 2441039; EP 2452247 and EP 2569716; U.S. Pat. Nos. 8,091,032 and 8,145,637 and United States Patent Publications No. 2010/0045705; 2010/0082618; 2011/0238408; 2013/0127748; 2013/0182963; 2013/0218902; 2014/0046955; 2014/0052281 and 2014/0053228 and PCT Publications No. WO 2010/144766; WO 2011/005318; WO 2011/119171 and WO 2011/021202).

Despite all such advances, a need remains for computer systems that are specially adapted to propagate content over a dynamic network, substantially in real time, by virtue of the locational proximity of network-joined Client Computers. The invention is directed to this and other needs.

SUMMARY OF THE INVENTION

The invention concerns computer systems that are specially adapted to propagate content over a dynamic network, substantially in real time, by virtue of the locational proximity of interconnected network-joined Client Computers, at least one of which communicates with an interconnected Client Computer via infrared signal, laser pulse, or radio frequency. Preferably, the content will also be weighted (for example, proximity-weighted, rank-weighted, topic-weighted, query-weighted, time-weighted, location-weighted, locality-weighted, vote-weighted, segment-weighted, geophysically-weighted, etc.). The invention particularly concerns such computer systems that employ more than one such weighting. The invention particularly concerns such computer systems that operate using, or through, mobile devices, particularly for distributed computing applications, including social media applications and communications applications conducted over Restricted Computer Networks. The invention particularly concerns such computer systems that comprise an interconnected Client Computer that is mounted in a vehicle, installed on or in a structure or is a component of a drone device.

In detail, the invention pertains to a computer system for disseminating content among interconnected Client Computers, wherein the computer system comprises:

a content-providing Client Computer (I) and a content-receiving Client Computer (II), interconnected, via a digital or an analog connection, with one another directly or through one or more other Client Computer(s) to form a distributed communications network; wherein:

-   -   (A) one or more of:         -   (1) the content-providing Client Computer (I);         -   (2) the content-receiving Client Computer (II); and/or         -   (3) the other Client Computer(s), if the content-providing             Client Computer (I) and the content-receiving Client             Computer (II) are interconnected to the distributed             communications network via the other Client Computer(s);         -   communicates with an interconnected Client Computer via an             infrared signal, a laser pulse, or a radio frequency;     -   (B) the content-providing Client Computer (I) is adapted to         transmit data comprising text content, sound content, image         content and/or video content, wirelessly or via a wired         connection, to the content-receiving Client Computer (II) either         directly or through the one or more other Client Computer(s) of         the distributed communications network;     -   (C) the content-receiving Client Computer (II) is adapted to         receive at least a subset of the transmitted data of the         content-providing Client Computer (I); wherein the content of         the received or presented content adjusts in response to changes         in:         -   (i) a Favorability Value assigned by the content-providing             Client Computer (I); and/or         -   (ii) a weighting preference assigned by the             content-receiving Client Computer (II); and/or         -   (iii) where the Client Computers (I) and (II) are             interconnected to one another through one or more other             Client Computer(s), a Favorability Value assigned by one or             more of the other Client Computer(s);         -   thereby disseminating content across the distributed             network;         -   and wherein the Favorability Value is determined by a             Favorability Function that considers one or more             Favorability Parameter(s), with the proviso that when             selected Favorability Parameters include both vote and time,             the Favorability Function shall additionally consider one or             more additional Favorability Parameter(s).

The invention additionally includes the embodiment of such computer system wherein the content-receiving Client Computer (II) of the computer system stores received content in a Content Stack memory; wherein content stored in the Content Stack memory rises in response to increases in Favorability Value of the content, and/or falls in the Content Stack memory in response to decreases in Favorability Value, such that the number or amount of content stored in the Content Stack memory remains within available processing and bandwidth parameters.

The invention additionally includes the embodiment of such computer systems wherein the content-receiving Client Computer (II) of the computer system presents a subset of the stored received content to its user, wherein the presented content is stored in a Presentation Stack memory; wherein content stored in the Presentation Stack memory:

-   -   (A) rises in the Presentation Stack memory in response to:         -   (1) increased proximity between the content-receiving Client             Computer (II) and the content-providing Client Computer (I);         -   (2) increases in the Favorability Value of the content:             -   (i) assigned by the content-providing Client Computer                 (I); and/or             -   (ii) assigned by the content-receiving Client Computer                 (II); and/or             -   (iii) where the Client Computers (I) and (II) are                 interconnected to one another through one or more other                 Client Computer(s), assigned by one or more of the other                 Client Computer(s);         -   and/or         -   (3) changes in weighting preferences applied by the             content-receiving Client Computer (II) that increase its             user's desire for such content;     -   and/or     -   (B) falls in the Presentation Stack memory in response to:         -   (1) decreased proximity between the content-receiving Client             Computer (II) and the content-providing Client Computer (I);         -   (2) decreases in the Favorability Value of the content:             -   (i) assigned by the content-providing Client Computer                 (I); and/or             -   (ii) assigned by the content-receiving Client Computer                 (II); and/or             -   (iii) where the Client Computers (I) and (II) are                 interconnected to one another through one or more other                 Client Computer(s), assigned by one or more of the other                 Client Computer(s);         -   and/or         -   (3) changes in weighting preferences applied by the             content-receiving Client Computer (II) that decrease its             user's desire for such content;     -   such that the number or amount of content stored in the         Presentation Stack memory of Client Computer (II) remains within         user-selected parameters.

The invention additionally includes the embodiment of such computer systems wherein the presented content is weighed based on one or more weighting preference(s) selected from the group consisting of: proximity-weighting, rank-weighting, topic-weighting, query-weighting, time-weighting, location-weighting, locality-weighting, vote-weighting, segment-weighting and geophysical-weighting.

The invention additionally includes the embodiment of such computer systems wherein the one or more of:

-   -   (1) the content-providing Client Computer (I);     -   (2) the content-receiving Client Computer (II); and/or     -   (3) the other Client Computer(s), if the content-providing         Client Computer (I) and the content-receiving Client         Computer (II) are interconnected to the distributed         communications network via the other Client Computer(s);         communicates with an interconnected Client Computer via an         infrared signal, laser pulses or a radio frequency.

The invention additionally includes the embodiment of such computer systems wherein the one or more of:

-   -   (1) the content-providing Client Computer (I);     -   (2) the content-receiving Client Computer (II); and/or     -   (3) the other Client Computer(s), if the content-providing         Client Computer (I) and the content-receiving Client         Computer (II) are interconnected to the distributed         communications network via the other Client Computer(s);         is mounted in a vehicle, installed in or on a structure or is a         component of a drone device and communicates with an         interconnected Client Computer.

The invention additionally includes the embodiment of such computer systems wherein the network additionally comprises a Content-Monitoring Computer.

The invention additionally includes the embodiment of such computer systems wherein the network comprises a Restricted Computer Network.

The invention additionally includes the embodiment of such computer systems wherein the content-receiving Client Computer (II) presents received content to a user using a graphical user interface.

The invention additionally includes the embodiment of such computer systems wherein the content-providing Client Computer (I) is additionally adapted to receive at least a subset of text content, sound content, image content and/or video content transmitted from another Client Computer, and wherein at least a subset of the content received by the content-receiving Client Computer (II) directly or indirectly from the content-providing Client Computer (I), and presented to the user of the content-receiving Client Computer (II), was received by the content-providing Client Computer (I) from the other Client Computer.

The invention additionally includes the embodiment of such computer systems wherein the content-receiving Client Computer (II) is additionally adapted to transmit data comprising text content, sound content, image content and/or video content, wirelessly or via a wired connection, to another Client Computer either directly or through the one or more other Client Computer(s) of the distributed communications network.

The invention additionally pertains to a computer-implemented method for disseminating content among interconnected Client Computers, wherein the method enables the interconnection, via a digital or an analog connection, of a content-providing Client Computer (I) and a content-receiving Client Computer (II), directly or through one or more other Client Computer(s), to thereby form a distributed communications network, wherein:

-   -   (A) one or more of:         -   (1) the content-providing Client Computer (I);         -   (2) the content-receiving Client Computer (II); and/or         -   (3) the other Client Computer(s), if the content-providing             Client Computer (I) and the content-receiving Client             Computer (II) are interconnected to the distributed             communications network via the other Client Computer(s);         -   communicates with an interconnected Client Computer via an             infrared signal, a laser pulse, or a radio frequency;     -   (B) the content-providing Client Computer (I) transmits data         comprising text content, sound content, image content and/or         video content, wirelessly or via a wired connection, to the         content-receiving Client Computer (II) either directly or         through the one or more other Client Computer(s) of the         distributed communications network; and     -   (C) the content-receiving Client Computer (II) receives at least         a subset of the transmitted data of the content-providing Client         Computer (I); wherein the content of the received or presented         data adjusts in response to changes in:         -   (i) a Favorability Value assigned by the content-providing             Client Computer (I); and/or         -   (ii) a weighting preference assigned by the             content-receiving Client Computer (II); and/or         -   (iii) where the Client Computers (I) and (II) are             interconnected to one another through one or more other             Client Computer(s), a Favorability Value assigned by one or             more of the other Client Computer(s);     -   thereby disseminating content across the distributed network;     -   and wherein the Favorability Value is determined by a         Favorability Function that considers one or more Favorability         Parameter(s), with the proviso that when selected Favorability         Parameters include both vote and time, the Favorability Function         shall additionally consider one or more additional Favorability         Parameter(s).

The invention additionally includes the embodiment of such computer-implemented method wherein the method permits the content-receiving Client Computer (II) of the computer system to store received content in a Content Stack memory; wherein the method permits content stored in the Content Stack memory to rise in response to increases in Favorability Value of the content, and/or to fall in the Content Stack memory in response to decreases in Favorability Value, such that the number or amount of content stored in the Content Stack memory remains within available processing and bandwidth parameters.

The invention additionally includes the embodiment of such computer-implemented methods wherein the method permits the content-receiving Client Computer (II) of the computer system to present a subset of the stored content to its user, wherein the presented content is stored in a Presentation Stack memory; wherein the method permits content stored in the Presentation Stack memory:

-   -   (A) to rise in the Presentation Stack memory in response to:         -   (1) increased proximity between the content-receiving Client             Computer (II) and the content-providing Client Computer (I);         -   (2) increases in the Favorability Value of the content:             -   (i) assigned by the content-providing Client Computer                 (I); and/or             -   (ii) assigned by the content-receiving Client Computer                 (II); and/or             -   (iii) where the Client Computers (I) and (II) are                 interconnected to one another through one or more other                 Client Computer(s), assigned by one or more of the other                 Client Computer(s);         -   and/or         -   (3) changes in the weighting preferences applied by the             content-receiving Client Computer (II) that increase its             user's desire for such content;     -   and/or     -   (B) to fall in the Presentation Stack memory in response to:         -   (1) decreased proximity between the content-receiving Client             Computer (II) and the content-providing Client Computer (I);         -   (2) decreases in the Favorability Value of the content:             -   (i) assigned by the content-providing Client Computer                 (I); and/or             -   (ii) assigned by the content-receiving Client Computer                 (II); and/or             -   (iii) where the Client Computers (I) and (II) are                 interconnected to one another through one or more other                 Client Computer(s), assigned by one or more of the other                 Client Computer(s);         -   and/or         -   (3) changes in the weighting preferences applied by the             content-receiving Client Computer (II) that decrease its             user's desire for such content;     -   such that the number or amount of content stored in the         Presentation Stack memory of the Client Computer remains within         user-selected parameters.

The invention additionally includes the embodiment of such computer-implemented methods wherein the method permits the presented content to be weighted based on one or more weighting preference(s) selected from the group consisting of: proximity-weighting, rank-weighting, topic-weighting, query-weighting, time-weighting, location-weighting, locality-weighting, vote-weighting, segment-weighting, and geophysical-weighting.

The invention additionally includes the embodiment of such computer-implemented methods wherein the one or more of:

-   -   (1) the content-providing Client Computer (I);     -   (2) the content-receiving Client Computer (II); and/or     -   (3) the other Client Computer(s), if the content-providing         Client Computer (I) and the content-receiving Client         Computer (II) are interconnected to the distributed         communications network via the other Client Computer(s);         communicates with an interconnected Client Computer via an         infrared signal, a laser pulse or a radio frequency.

The invention additionally includes the embodiment of such computer-implemented methods wherein the one or more of:

-   -   (1) the content-providing Client Computer (I);     -   (2) the content-receiving Client Computer (II); and/or     -   (3) the other Client Computer(s), if the content-providing         Client Computer (I) and the content-receiving Client         Computer (II) are interconnected to the distributed         communications network via the other Client Computer(s);         is mounted in a vehicle, installed in or on a structure or is a         component of a drone device and communicates with an         interconnected Client Computer.

The invention additionally includes the embodiment of such computer-implemented methods wherein the method permits the network to additionally comprise a Content-Monitoring Computer.

The invention additionally includes the embodiment of such computer-implemented methods wherein the method permits the network to comprise a Restricted Computer Network.

The invention additionally includes the embodiment of such computer-implemented methods wherein the content-receiving Client Computer (II) presents the received data to the user using a graphical user interface.

The invention additionally includes the embodiment of such computer-implemented methods wherein the content-providing Client Computer (I) additionally receives at least a subset of text content, sound content, image content and/or video content transmitted from another Client Computer, and wherein at least a subset of the data received by the content-receiving Client Computer (II) directly or indirectly from the content-providing Client Computer (I), and presented to the user of the content-receiving Client Computer (II), was received by the content-providing Client Computer (I) from the other Client Computer.

The invention additionally includes the embodiment of such computer-implemented methods wherein the content-receiving Client Computer (II) additionally transmits data comprising text content, sound content, image content and/or video content, wirelessly or via a wired connection, to another Client Computer either directly or through the one or more other Client Computer(s) of the distributed communications network.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 shows a map of interconnected Client Computers of a distributed computer system of the present invention.

FIG. 2 illustrates a data race.

FIGS. 3A-3B illustrate how the memory stacks of two Client Computers (Client Computers 1 of User A and Client Computer 2 of User B) change in response to the sharing of their content.

FIGS. 4A-4B illustrate the ability of the present invention to use proximity-weighting.

FIG. 5 presents an illustrative text input screen of a touchscreen mobile phone or tablet Client Computer device.

FIG. 6 illustrates a user interface of a touchscreen mobile phone or tablet Client Computer device.

FIG. 7 illustrates the ability of an exemplary user interface to permit a user to perceive desired content.

FIG. 8 illustrates how one may manipulate an exemplary user interface to perceive desired content, showing an illustrative topic conversation among several attendees of a lecture.

FIGS. 9A-9C illustrate the use of an exemplary user interface of a touchscreen mobile phone or tablet Client Computer device to sort and group content for presentation to a user. FIG. 9A shows the use of a sorting graphical element to group content for presentation to a user. FIG. 9B shows the use of a drag and drop capability to group content for presentation to a user. FIG. 9C shows the use of a graphical element selection capability to group content for presentation to a user.

FIGS. 10A-10B illustrate the ability of the invention to use location-weighting to form “heat maps” of recent activity (FIG. 10A) and rank activity (FIG. 10B).

FIG. 11 shows a user interface that exploits a camera functionality of a Client Computer. Content is shown in augmented reality balloons, which are generally localized (so as to preserve the anonymity of the content provider in the absence of permission), or in augmented reality callouts that are particularly localized to Client Computers whose users have granted identification permissions to the recipient.

DETAILED DESCRIPTION OF THE INVENTION

The invention concerns computer systems that are specially adapted to propagate content over a dynamic network, substantially in real time, by virtue of the locational proximity of interconnected network-joined Client Computers, at least one of which communicates with an interconnected Client Computer via infrared signal, laser pulse, or radio frequency. Preferably, the content will also be weighted (for example, proximity-weighted, rank-weighted, topic-weighted, query-weighted, time-weighted, location-weighted, locality-weighted, vote-weighted, segment-weighted, geophysically-weighted, etc.). The invention particularly concerns such computer systems that employ more than one such weighting. The invention particularly concerns such computer systems that operate using, or through, mobile devices, particularly for distributed computing applications, including social media applications and communications applications conducted over Restricted Computer Networks. The invention particularly concerns such computer systems that comprise an interconnected Client Computer that is mounted in a vehicle, installed on or in a structure or is a component of a drone device.

I. The Preferred Computers of the Computer Systems of the Present Invention

The preferred computers of the computer systems of the present invention are “Client Computers” (also referred to as “clients”) that will preferably possess a means for inputting data, means for receiving and providing data to other interconnected Client Computers (clients) of the network, computer (or machine)-addressable memory configured to store content and/or to store programming instructions, and a computer “processor” configured to process data (including content) and to implement programming instructions.

The programming instructions stored in a Client Computer (or otherwise provided to such Client Computer) enables that Client Computer to provide content to other Client Computers of a common network (acting as a distributed server), to receive content provided from other Client Computer(s) of the common network, and, preferably, to store (permanently, transiently, or for a user-set time duration) content provided from other Client Computers that are joined to such network. The programming instructions may be a computer “App,” a firmware program, a computer program stored in memory, etc.). Alternatively, the Client Computer may join and participate with a computer system of the present invention by accessing a website, LAN, WLAN, etc. that communicates with a server.

Additionally, the programming instructions enables a Client Computer to determine the “proximity” between such Client Computer and other Client Computer(s) of a common network, based upon the locational position of such Client Computer and the locational position of such other Client Computer(s). Locational information may be input manually (as through an “app” or input interface), but more preferably will be determined automatically by the Client Computer (e.g., using an internal or external global positioning system (GPS) receiver, or with reference to cellular signaling towers, or with reference to a fixed land-based internet access point, etc.). Preferably, the set of instructions stored in the Client Computer enables such Client Computer to establish a searchable and/or sortable database of received content. The establishment of such a database enables each Client Computer to independently and dynamically present to its user content that is weighted by proximity, and also by topic ranking, topic keyword, time or location of interest.

Preferably, such Client Computers will also have an output or presentation capability (e.g., a video output (e.g., an LCD or LED screen, etc.), and/or an audio output (e.g., a speaker, tone generator, etc.) so as to enable a user of a Client Computer to perceive provided or received content. The invention, however, encompasses Client Computers that lack such output capability.

A Client Computer of the present invention may be mounted in a vehicle (which may be a ground-travelling vehicle (e.g., a car, truck, farming vehicle, military vehicle, etc.), or an aerial vehicle (e.g., a civilian or military plane, balloon, jet, spacecraft, etc.), or a water-travelling vehicle (e.g., a civilian or military boat, ship, submarine, etc.), etc.), or may be installed in, or on, a structure (e.g., a tower, street lamp, building, air-traffic control tower, bridge, pier, tunnel, lighthouse, water buoy, etc.), or may be a component of a drone device (i.e., a vehicle that operates without an onboard human presence) so as to extend the communication range of a computer network formed by a computer system of the present invention that includes such Client Computer. Such Client Computers may have output capabilities, however, the possession of such capabilities by such Client Computers is optional. Such vehicles, structures or drone devices may be “autonomous,” so as to be capable of functioning without human communication or interaction. Alternatively, such vehicles, structures or drone devices may be “semi-autonomous,” so as to be capable of functioning with minimal, intermittent or non-minimally delayed human communication or interaction. In a further alternative, such vehicles, structures or drone devices may be “non-autonomous,” so as to be able to function only if at least partially controlled in real-time or via minimally-delayed communication or interaction by one or more remotely-situated human drivers, pilots, operators, handlers, etc. The drone devices that may comprise such Client Computers may be ground-traveling drone devices (e.g., a robot explosive ordnance disposal (EOD) vehicle, a robotic carrier, a robotic tank, a robotic package delivery vehicle, etc.), aerial drone devices (e.g., a missile, a precision-guided munition, a surveillance drone, a satellite, etc.,), or a water-traveling drone device (e.g., a submersible drone device, a surface-traveling drone device, etc.).

The Client Computers of the present invention will preferably be mobile devices, such as smartphones, laptops, tablets, smartwatches (e.g., Moto 360®), handheld gaming systems, optical head-mounted displays (OHMD) (e.g., Google Glass®, Oculus Rift® (Oculus/Facebook Corporation), helmet visors, night vision goggles, vehicular heads-up displays, etc.; see, e.g., U.S. Pat. Nos. 8,594,338; 8,536,776; 8,531,418; 8,487,233; 8,467,133; 8,436,788; 8,431,881; 8,384,999; 8,355,610; 8,269,159; 8,267,691; 8,138,991; 8,136,170; 7,841,026; 7,800,043; 7,791,809; 7,755,831; 7,710,654; 7,598,849; 7,530,704; 7,496,293; etc.). Although particularly adapted for use with inter-communicating mobile devices, the Client Computers of the computer systems of the present invention may comprise any form of computer (including stationary desktop computers and servers). The communication range of the Client Computers of the present invention may be up to 50 feet, up to 100 feet, up to 250 feet, up to 500 feet, up to 0.25 miles, up to 0.5 miles, up to 1 mile, up to 2 miles, up to 5 miles, up to 10 mile, up to 20 miles, up to 50 miles, up to 100 miles, or more than 100 miles.

The users of the Client Computers of the present invention may be unrelated individuals, groups or entities (such as people visiting a park, groups from different organizations, stores, businesses, etc.). Alternatively, the users of the Client Computers of the present invention may be related individuals, groups or entities (such as medical, security, fire or emergency personnel responding to an accident or other incident, or military personnel engaged in a joint activity). For example, emergency or other personnel responding to an incident (e.g., a burning building, etc.) could use the present invention to remain in communication with one another automatically (and particularly, have the ability to automatically communicate with other responders located near to them). Alternatively, as indicated above, the Client Computers may be installed in vehicles, on structures (e.g., towers), as a component of drones, etc., and may be unattended by any user. For example, although such Client Computers could be manually controlled by a remote user, they may alternatively be capable of semi-autonomous activity, or could be autonomously controlled by an on-board (or remote) computer.

II. Content Sharing by the Client Computers of the Computer Systems of the Present Invention

As indicated above, the computer systems of the present invention are preferably composed of two or more Client Computers that are interconnected, digitally and/or via an analog connection, and which thus form a communication network capable of providing data comprising “content” to, and of receiving data comprising “content” from, other Client Computers that are joined to the network (collectively, referred to as “sharing” content).

As used herein, the term “content” is intended to include a digital or analog communication that contains information relevant to a particular “topic” (i.e., subject, event, name, etc.). Each topic may have one or more subtopics (“threads”). Content is said to be “related” if it pertains to, is about, related information.

The term “content” may thus comprise one, or any combination, of:

-   A. text content (e.g., a comment, opinion, remark, response, vote,     text message, symbol, letter, emoticon, label (e.g., text that     serves to caption, describe, characterize or name other text content     or non-textual content such as sound content, image content, video     content, etc., or which is associated with such other text content     or non-textual content); textual table, textual data (e.g., a text     table, numerical spreadsheet, database data, etc.). Text content is     provided, for example, in an ASCII, UTF-8, MIME, TXT, or other text     character file. Such textual message content will preferably     comprise brief textual messages (e.g., a textual message having no     more than 500 characters (i.e., letters, symbols, emoticons, etc.),     no more than 300 characters, no more than 200 characters, no more     than 150 characters, or most preferably, no more than 100 characters -   B. sound content (e.g., a voice recording, song, music, tone,     musical note, sound effect, street sound, video soundtrack,     sound-embedded data (e.g., tonal data), etc.), provided, for example     in a 3gp, aac, act, AIFF, ALAC, amr, atrac (.wav), Au, awb, dct,     dss, dvf, flac, gsm, iklax, IVS, m4a, m4p, mmf, mp3, mpc, msv, ogg,     Opus, ra & rm, raw, vox, way, wavpack, wma, or other type of audio     file; -   C. image content (e.g., a pixel-based image, a vector image, a     photograph, a holograph, a virtual reality image, image-embedded     data (e.g., a barcode, data matrix, Aztec code, QR code, etc.), a 3D     image, etc.) provided, for example in a JPEG/JFIF, JPEG 2000, Exif,     TIFF, RAW, GIF, BMP, PNG, PPM, PGM, PBM, PNM, PFM, PAM, WEBP, an HDR     Raster format, RGBE, IFF-RGFX, JPEG XR (New JPEG standard based on     Microsoft HD Photo), TGA (TARGA), ILBM (IFF-style format for up to     32 bit in planar representation, plus optional 64 bit extensions,     DEEP (IFF-style), AI, IMG (Graphical Environment Manager image file;     planar, run-length encoded), PCX (Personal Computer eXchange), ECW     (Enhanced Compression Wavelet), IMG (ERDAS IMAGINE Image), SID     (multiresolution seamless image database, MrSID), CD5 (Chasys Draw     Image), FITS (Flexible Image Transport System), PGF (Progressive     Graphics File), XCF (eXperimental Computing Facility format, native     GIMP format), PSD (Adobe PhotoShop Document), PSP (Corel Paint Shop     Pro), VICAR file format (NASA/JPL image transport format), HVD     (Holographic Versatile Disc), 3DM, 3DS, MAX 3DS, OBJ, A2C, B3D,     BLEND, BRS, BR6, CCP, CG, CGFX, CHR, DAE, DAZ, DSF, DWF, FACEFX,     FBX, FLT, FPF, IV, LND 3D, LWO, LWS, LXO, MA, MB, MDD, MXS, SDB,     SHP, SKP, STP, U3D, VUE, PDF or other image file; or -   D. video content (e.g., for example, a moving image, video image,     movie, augmented reality, video-embedded data, etc.) provided, for     example in a 3GP, ASF, AVI, RIFF, DVR-MS, Flash Video (FLV, F4V),     IFF (first platform-independent container format), Matroska (MKV),     MJ2, QuickTime, MPEG (including MPEG-1, MPEG-2, MPEG-TS and MPEG-4     Part 12), MP4, JPEG 2000 Part 12, Ogg, RM (RealMedia), vrcinema3D,     or other video file.     Such sound, image, video or text files may be of any size that can     be provided (in whole or in part (e.g., in packets, etc.) over the     employed network. Preferably, such sound, image, video or text files     will be less than 1 GB, less than 500 MB, less than less than 200     MB, less than 100 MB, less than 50 MB, less than 20 MB, less than 10     MB, less than 5 MB, less than 2 MB, less than 1 MB, less than 500     KB, less than 200 KB, less than 100 KB, less than 50 KB, less than     20 KB, or less than 10 KB in size. However, such text, sound, image     or video files may be larger, for example, they may be 10 GB or more     in size, 100 GB or more in size, 1 TB or more in size, 10 TB or more     in size, 100 TB or more in size, 1 PB or more in size, etc., so as     to permit the transmission, transfer, relay, broadcast, or otherwise     dissemination or distribution of “large data” or “big data” (e.g.,     U.S. Pat. Nos. 10,223,327; 10,102,261; 10,055,469; 10,037,303). Such     larger files are particularly relevant to networks of the present     invention that comprise a non-distributed computer system. For     example, data from multiple Client Computers may be transmitted to a     centralized server, which may then combine the data to provide a     database or datamap that may then be transmitted in whole or in     part, to one or more Client Computers (see, e.g., FIGS. 10A-10B and     FIG. 11). In one embodiment, multiple Client Computers may transmit     parts of a file to a centralized server, which may then combine the     received parts to form a composite file or assemble the received     parts to form a complete file; the composite or assembled file or     complete file may then be provided to one or more of such or other     Client Computers of the network. Alternatively, such centralized     server may transmit parts of a file to one or more of such or other     Client Computers of the network, which recipient Client Computer(s)     may then combine the received parts to form a composite file or     assemble the received parts to form a complete file; the composite     or assembled file or complete file may then be provided to one or     more other Client Computers of the network and/or to a centralized     server. In a further embodiment, one Client Computer may transmit     parts of a file to a second Client Computer, which may then combine     the received parts to form a composite file or assemble the received     parts to form a complete file; the composite or assembled file or     complete file may then be provided to one or more other Client     Computers of the network and/or to a centralized server.

As stated above, a computer of a computer system of the present invention has the ability to receive content from other computers of the computer system, and preferably also has the ability to provide content to such other computers (i.e., the ability to “share content”). As used herein, the term “receive content” denotes the capacity of a Client Computer to accept, employ or otherwise access, by any means, content that has been provided by another Client Computer of a computer system of the present invention. As used herein, the term “provide content” denotes the capacity to transmit, transfer, relay, broadcast, or otherwise disseminate or distribute content, by any means, so that content provided by one Client Computer is, or may be made, accessible to other Client Computers of a computer system of the present invention. Such receiving and providing capabilities permit the dissemination of content by and among Client Computers. Additionally, such receiving and providing capabilities may be used to permit Content-Monitoring Computers (as discussed below) to conduct content data-mining, or to perform content backups for Client Computers (e.g., continuously, automatically at periodic intervals, or manually upon the request of the user of such Client Computer). Such content backups may be desirable in order to restore unsaved content if the Client Computer exits the network. Additionally, such receiving and providing capabilities can be used to permit Content-Monitoring Computers or Client Computers to obtain a log of accessed content.

Most preferably, Client Computers will be directed to present content to its user. As used herein, the term “present” content denotes displaying content (for example, in the case of content involving textual, image or video content, displaying such content on a screen, projection or other visible output) or performing or playing content (for example, in the case of content involving sound). Preferably, such content will be provided in “real time” (i.e., with sufficient immediacy as to provide such content to a recipient Client Computer at substantially the same actual time at which such content was provided by the providing Client Computer). Alternatively, in an embodiment in which content is stored (for example, when a non-distributed computer system having a centralized server is used), historical content can be provided, permitting a user to perceive content that had been provided at an earlier time, or during a user-selected time period in the past).

As discussed below, Client Computers may be required to obtain permission or authorization to join a network of the present invention, and may require additional permission or authorization before being able to provide content to other Client Computers of a network. More preferably, however, a Client Computer will join to a network of a computer system of the present invention automatically upon recognizing the presence of a second Client Computer, without any need for the granting of permission from such Client Computer or from other Client Computers of such computer system. Although Client Computers of a computer system of the present invention may be directed to provide the names or usernames of their respective users to other Client Computers, it is preferred that a user's participation in a common network be anonymous to other users. To facilitate comprehension of content discussions, a Client Computer may ascribe a transient token name to content contributors. Thus, for example, the first user to contribute content may be identified as “Anon01,” and the second user to contribute related content may be identified as “Anon02,” etc. In such a manner, users corresponding to “Anon01” and “Anon02” may converse with one another anonymously.

III. Preferred Network Configurations of the Computer Systems of the Present Invention

As indicated above, the computer systems of the present invention comprise two or more Client Computers that have been “joined to a network” and are thus interconnected with one another via a digital or analog connection. Two or more Client Computers that are joined to the same network are referred to herein as being joined to a “common” network. A digital connection involves the physical transfer of data (a digital bit stream), typically represented as an electromagnetic, optical or infrared signal that is digitized to a stream of zeros and ones. The data signals are easily compressed and, as such, can be transmitted with accuracy and speed; the transmission is typically discontinuous and thus can be broken into packets as discrete message. Digital connections are intolerant to noise. In contrast, an analog connection transmits data using a continuous signal which varies in amplitude, phase, or some other property in proportion to that of a variable. Analog connections are very tolerant to noise, make good use of bandwidth, involve low costs, and are easy to manipulate mathematically. A particular signal (e.g., an infrared signal, laser pulses, radio frequency transmissions, etc.) may be configured for use in either a digital connection or an analog connection through the use of a digital-to-analog converter (DAC) and/or an analog-to-digital converter (ADC) (see, e.g., U.S. Pat. Nos. 5,379,040; 6,420,988; 10,206,202; 10,218,786; 10,225,017; 10,225,021; 10,225,299; 10,228,247; 10,230,419; 10,231,190; 10,237,317; Walden, R. H. (1999) “Analog-to-Digital Converter Survey and Analysis,” IEEE J. Selected Areas in Communications 17(4):539-550; Black, B. (1999) “Analog-to-Digital Converter Architectures and Choices for System Design,” Analog Dialogue 33-8; pages 1-4; Lee, H.-S. et al. (2008) “Analog-to-Digital Converters: Digitizing the Analog World,” Proc. IEEE 96(2):323-334; Luschas, S. et al. (2004) “Radio Frequency Digital-To-Analog Converter,” IEEE J. Solid-State Circuits 39(9):1462-1467; Valley, G. C. (2007) “Photonic Analog-to-Digital Converters,” Optics Express 15(5):1955-1982; van de Plassche (2003) CMOS INTEGRATED ANALOG-TO-DIGITAL AND DIGITAL-TO-ANALOG CONVERTERS, 2^(nd) Ed., Kluwer Academic Publishers, Dorddrecht).

The computer systems of the present invention may be of any topology capable of supporting the operations described herein. Connections and networks included in the connections may comprise the internet, local networks, web servers, file servers, routers, databases, computers, servers, network appliances, cell phones or any other computing devices capable of sending and receiving data, especially digital data. The computer systems of the present invention may comprise computing devices connected via cables, IR ports, wireless signals, or any other means of connecting multiple computing devices.

The communication networks of the present invention may be of any type and may have any form of network architecture, including any of the following: a point to point network, a broadcast network, a wide area network, a local area network, a telecommunications network, a data communication network, a computer network, an ATM (Asynchronous Transfer Mode) network, a SONET (Synchronous Optical Network) network, a switched fabric network (e.g., an INFINIBAND® switched fabric network), a SDH (Synchronous Digital Hierarchy) network, a wireless network, and a wireline network. The networks of the present invention may comprised wired connections (e.g., Ethernet, fiber optic, etc.) or non-wired connections (for example, an infrared channel (e.g., involving light having a wavelength of from about 700 nm (430 THz) to about 1 mm (300 GHz), laser pulses (for example, involving semiconductor lasers having wavelengths of from about 400 nm to about 20 μm, e.g., AlGaInP, AlGaAs lasers (having wavelengths of from about 630 nm to about 900 nm), InGaAsP lasers (having wavelengths of from about 1 μm to about 2.1 μm), etc.)), or a radio frequency (for example, radio having wavelengths of from about 30 Hz to 300 GHz), etc.)), and may additionally comprise, or include, wired (e.g., Ethernet, fiber optic, etc.) connections or non-wired connections. The network may have any topology (e.g., a bus, star, or ring topology, etc.).

The individual computers of the computer systems of the present invention may communicate with one another via any communication protocol used to communicate among or within computing devices. including without limitation infrared signaling, laser pulse signaling, or communication over radio frequency or radio frequencies. Most preferably, a Client Computer of the present invention will join to a network wirelessly and participate in content sharing with other Client Computers of the present invention utilizing any protocol or protocols used to communicate among mobile devices.

The communication protocol employed with respect to a particular computer system will preferably be selected based on factors such as the anticipated data capacity that is to be communicated by the computer system, the anticipated distance between communicating Client Computers, etc.

For example, particularly involving communications with, or networks that include, submerged underwater Client Computers, such as those installed in a submarine, submersible drone, etc., the communicating Client Computers may be adapted to communicate using Extremely Low Frequency (ELF) radio signaling (e.g., 3-30 Hz) or Super Low Frequency (SLF) radio signaling (e.g., 30-300 Hz) or Ultra Low Frequency (ULF) (e.g., 300-3,000 Hz) or Very Low Frequency (VLF) radio signaling (e.g., 3-30 kHz).

Particularly in applications involving communications with, or networks that include, aerial Client Computers, such as those installed in an airplane, missile, flying drone, etc., the communicating Client Computers may be adapted to communicate using Low Frequency (LF) radio signaling (e.g., 30-300 kHz) or Medium Frequency (MF) radio signaling (e.g., 300-3,000 kHz) or High Frequency (HF) radio signaling (e.g., 3-30 MHz) or Very High Frequency (VHF) radio signaling (e.g., 30-300 MHz). High Frequency (HF) radio signaling or Very High Frequency (VHF) radio signaling may also be particularly employed in applications involving communications with, or networks that include marine surface Client Computers, such as those installed in a ship, maritime vessel, surface water drone, etc., or networks that include land-based Client Computers, such as those installed in a structure, tower, street lamp, etc., or in a vehicle (e.g., a car, truck, personnel carrier, tank, land-surface drone, etc.).

Particularly in applications involving communications with, or networks that include, Client Computers that are near to one another, the communicating Client Computers may be adapted to communicate using Ultra High Frequency (UHF) radio signaling (300-3,000 MHz), such as Bluetooth® or a Bluetooth® implementation (e.g., Bluetooth® Low Energy (BLE)), Z-Wave, X10, SSL, HTML, XML, RDP, ICA, FTP, HTTP, TCP, IP, UDP, IPX, SPX, NetBIOS, NetBEUI, SMB, SMTP, Ethernet, ARCNET, Fiber Distributed Data Interface (FDDI), RS232, 3G/4G or Long Term Evolution (LTE), AMPS, TDMA, CDMA, GSM, EDGE, GPRS or UMTS, a Wi-Fi protocol (e.g., an IEEE 802.11, IEEE 802.11a, IEEE 802.11ac, IEE 802.11b, IEEE 802.11g, or IEEE 802.11n communication protocol), or a ZigBee® gateway communication protocol and direct asynchronous connections, or any combination thereof. As currently defined, ZigBee® gateways operate at a frequency of 2.4 to 2.4835 GHz (world-wide) 902 to 928 MHz (Americas and Australia) and 868 to 868.6 MHz (Europe) ISM bands, and have a data exchange rate of 250 kbits per second. Such gateways are particularly suitable for use in creating ad hoc personal area networks with small, low-power digital radios for low-power, low-bandwidth needs. ZigBee® wireless technology permits connected nodes to form a communications mesh and is particularly suited to networks having a star or tree topology. A master coordinator node controls other connected nodes. If a node cannot communicate with another node, the two may communicate by way of links to other nodes within range acting as repeaters. The ZigBee® platform can support up to 65,000 nodes. At present, a ZigBee® transceiver may have 16 channels and may have the ability to search for a channel having minimum interference. ZigBee® technology is reviewed in U.S. Pat. Nos. 9,980,277, 9,961,512, 9,912,446, 9,769,903, 9,749,774, 9,634,765, 9,591,728, 9,554,242, 9,459,604, 8,745,398, 8,718,798, in EP 2408146, and in WO 2018/170790 and WO 2018/157771, and by Ahamed, S. S. R. (2009) “The Role Of ZigBee® Technology In Future Data Communication System,” J. Theoret. Appl. Inform. Technol. 129-135; Kinney, P. (2003) “ZigBee® Technology: Wireless Control that Simply Works,” Home Toys pp 1-4; Ondrej, S. et al. (2006) “ZigBee® Technology and Device Design,” International Conference on Networking, International Conference on Systems and International Conference on Mobile Communications and Learning Technologies (ICNICONSMCL '06), Morne, Mauritius, pp. 129-129. ZigBee® Transceiver modules that may be employed in the Adapter Modules of the present invention are widely available commercially from Mouser Electronics, Newark element 14 and other companies. Exemplary ZigBee® gateway modules that may be employed in the Client Computers of the present invention include the ZB2430 ZigBee® Transceiver Module (AeroComm), a ZM-24 2.4 GHz ZigBee® Transceiver Module (RTI), an XB3-24Z8UM ZigBee® Transceiver Module (Digi International), a B+B WSD2C21150 ZigBee® Transceiver Module (B+B Smartworx), an ETRX357 ZigBee® Transceiver Module (Silicon Laboratories), an ATZB-S1-256-3-0-C ZigBee® Transceiver Module (Microchip), etc.

In contrast, particularly in applications involving communications with, or networks that include, Client Computers that are more distant from one another, or when a greater data capacity is to be communicated, the communicating Client Computers may be adapted to communicate using Super High Frequency (SHF) radio signaling (3-30 GHz), such as an 802.11n Wi-Fi protocol, or Extremely High Frequency (EHF), such as an 802.11ad Wi-Fi protocol.

The 802.11n standard supports a maximum theoretical transfer rate of 300 Mbps (or 450 Mbps when using three antennae). The 802.11n standard uses MIMO (Multiple Input Multiple Output) where multiple transmitters/receivers operate simultaneously at one or both ends of the link. This capability provides a significant increase in data throughput without needing a higher bandwidth or a higher transmission power. The 802.11n standard supports networks operating on the 2.4 GHz and/or 5 GHz band. In contrast, the 802.11ac standard supports speeds of several Gigabits per second, but works exclusively in the 5 GHz band. It supports up to eight spatial streams (compared with 802.11n's four streams), doubles the channel width up to 80 MHz, and uses a technology called beamforming. With beamforming, the antennae basically transmit the radio signals so they're directed at a specific device. The 802.11ac standard includes multi-user Multiple Input Multiple Output (MU-MIMO). Whereas MIMO of the 802.11n standard directs multiple streams to a single client, MU-MIMO can direct the spatial streams to multiple clients simultaneously. While MU-MIMO doesn't increase the speed to any single client, it can increase the overall data throughput of the entire network. Exemplary Wi-Fi cards that may be employed in the Adapter Modules of the present invention include the 802.11ac Wi-Fi cards: 7260HMW (fenvi), 9260HMW (fenvi), FV-T919 (fenvi), AC1300 (fenvi), BCM94352Z (Broadcom), 7260.HMWWB.R (Intel), 9260NGW (Intel), WN6607AH (HP).

The networks of the present invention may be either “non-distributed networks” or “distributed networks.” In the “non-distributed networks” of the present invention, Client Computers provide content to a centralized computer (such as a server), and receive content from the centralized server. Individual Client Computers play no role in disseminating content; such dissemination is accomplished when other Client Computers access the centralized computer and receive provided content from the centralized computer. In contrast, in the “distributed networks” of the present invention, each Client Computer joined to the network mediates the dissemination of received content to all other Client Computers joined to that network (and more preferably to all other Client Computers joined to any network) that are within communication range, preferably without any gateway node. The dissemination of content by the distributed networks of the present invention is accomplished by having a receiving Client Computer re-provide such content to such other Client Computers. Thus, in a non-distributed network of the present invention, content flows from Client Computers to a centralized computer and then from the centralized computer to other Client Computers and the virtual proximity of Client Computers (i.e., their connectivity to the same central computer) determines their ability to share content. In the distributed networks of the present invention, content flows across the network by “hopping” from one Client Computer to another, preferably without any gateway node, and the locational proximity of Client Computers determines their ability to share content. Distributed networks are the preferred networks of the present invention.

Distributed networks have been previously described in the context of “ad hoc” or “mesh” networks (see generally, Ahtiainen, A. et al. (2009) “Awareness Networking In Wireless Environments,” Vehicular Technol. Mag. IEEE 4(3):48,54; Li, J. et al. (2001) “Capacity of Ad Hoc Wireless Networks,” Proc. 7^(th) ACM Intl. Conf. on Mobile Computing and Networking, Rome, Italy, July 2001 (1-9); Broch, J. et al. (1998) “A Performance Comparison Of Multi-Hop Wireless Ad Hoc Network Routing Protocols,” MobiCom '98 Proceedings of the 4^(th) Annual ACM/IEEE Intl. Conf. on Mobile Computing and Networking, pages 85-97; Niazi, M. et al. (2009). “Agent based Tools for Modeling and Simulation of Self-Organization in Peer-to-Peer, Ad Hoc and other Complex Networks, Feature Issue,” IEEE Commun. Mag. 47(3):163-173; Lee, S.-B. et al. (2013) “Content Management In A Mobile Ad Hoc Network: Beyond Opportunistic Strategy,” Intl. J. Commun. Networks Distributed Syst. 10(2):123-145; Steudi, P. et al. (2008) “Demo Abstract Ad Hoc Social Networking using MAND,” Proc. 14^(th) Intl. Conf. on Mobile Computing and Networking (MobiCom '08) pp. 1-3; Li, D. et al. (2013) “Opinion Impact Models and Opinion Consensus Methods in Ad Hoc Tactical Social Networks,” Discrete Dynamics in Nature and Society (2013):Article ID 758079, pp. 1-6). However, the utility of such prior networks has not been fully established. Network flow has been deemed to be limited because the throughput available to each single node's applications is limited by the forwarding load imposed by distant nodes (Li, J. et al. (2001) “Capacity of Ad Hoc Wireless Networks,” Proc. 7^(th) ACM Intl. Conf. on Mobile Computing and Networking, Rome, Italy, July 2001 (1-9)). To address network flow issues, previously described ad hoc or mesh networks are configured to contain gateway nodes (see, e.g., U.S. Pat. Nos. 8,570,990; 8,690,381; 8,654,713; 8,681,655 and 8,638,686), or may restrict the ability of nodes to send data in real time (see, e.g., U.S. Pat. Nos. 6,850,511; 7,002,944; and 8,625,544), or may involve specific packet routing protocols (see, e.g., U.S. Pat. No. 8,582,502) or involve other restrictions.

A. Operation of a Preferred Distributed Network of the Present Invention

As described above, the Client Computers of the computer system of the present invention preferably form a distributed network in which content, provided from one Client Computer, is received by a second Client Computer, and provided from such second Client Computer to additional Client Computers, such that a network map comprises sets of Client Computer nodes that are each in communication with interlocking subsets of the Client Computers of the distributed network, in which the area covered by a particular subset reflects the communication range of the Client Computers (FIG. 1). FIG. 1 shows a map of interconnected Client Computers; for simplicity of illustration only three subsets of Client Computers are shown (dashed circles). As will be appreciated, however, each Client Computer serves as the node of a subset, such that a large number of interlocking subsets are formed. Client computers within a particular subset (e.g., the Client Computers of User A and User B in Subset 1, or the Client Computers of User B and User C in Subset 2) are capable of providing and receiving content to/from one another. Thus, although User C is “out of range” of User A, the invention permits User C and User A to nevertheless share content with one another, through the Client Computer of User B. User B is within both Subset 1 and Subset 2, and is thus in range of both User A and User C. Likewise, the distributed network formed by the present invention permits content to be exchanged and shared among all members of a network, even those located most distant from one another (e.g., User A and User Z).

This aspect of the present invention permits its distributed network to be “dynamic.” The distributed network dynamically and automatically adjusts to continue to provide content to the Client Computers of the network. For example, in FIG. 1, the Client Computers of User A and User C are able to share content with one another, through the Client Computer of User B. However, if User A were to move to be next to User Z, he would, throughout such journey, be continuously able to maintain content sharing with User C, through the Client Computers of other users. Indeed, within the communication range of their respective Client Computers, all of the users shown in FIG. 1 could move about freely without altering their content sharing ability or the content sharing abilities of any other user. Provided that at least one Client Computer is within communication range of another Client Computer, the “coverage” of their common network can dynamically grow, alter or migrate in response to changes in the locational positions of all other Client Computers. Thus, a salient benefit of the distributed networks of the present invention is that content provided by a user traverses across the entire network (“content flow”) so as to be accessible to all other users of the network.

Users may elect to not perceive particular content, or they may elect to view content relevant to topics of interest. However, because the selected content is stochastic and is carried in the network flow for content that a user has selected as being of interest, any responding content creates a potential for a “data race.” The occurrence of a data race reflects the capability that the present invention provides for Client Computers to “weight” received content. Users may thus “vote” to promote or disfavor a content that is received on their Client Computers, which then sends a message to other Client Computers, updating the vote value of such content.

As a consequence, a subsequent user may receive conflicting data with which to weight content (FIG. 2). FIG. 2 illustrates a data race. As shown in FIG. 2, User A provides content to the network. The content is received by Users B, C and D, who each vote (passively, in the case of User B, and actively, in the case of Users C and D). Client computers of all three users provide content to User D. In a data race, the first Client Computer to provide content to User D's Client Computer sets the weighting for the content. A data race may also result from the provision of dual (or multiple) versions of content that has developed discrepancies in the course of being routed over the network. For example, the same content may be provided to other Client Computers of the network (as it is being routed from one Client Computer to another across the network). A Client Computer may therefore, for example, receive content having n votes from one Client Computer, and the same content, but with m votes, from a different Client Computer.

A data race is not a desired means of distributing content across the networks of the present invention. To address and resolve such data race issues, it is preferred for each Client Computer (and/or each user) to have a unique identifier coding. Preferably, each content provided to the network will also have a unique identifier coding. Preferably, therefore, when a user votes to promote or disfavor a particular content, the identifier coding of the user or Client Computer is attached to the comment, and saved on the user's Client Computer. When “duplicate” versions of a content are received, or when votes regarding such content is received, the user's Client Computer takes the union of the data, such that a new version is created consisting of the content and the union of votes (by user or Client Computer identifier coding) between the incoming vs. existing versions of the comment). This new version is then provided to other Client Computers, and the process repeats (until the content “dies” from lack of vote or distributing Client Computers). Thus, in the data race scenario of FIG. 2, the User D Client Computer will take the union of the incoming votes in order to determine the weighting to be used by User D, and to be propagated to other Client Computers by User D. This attribute of the present invention also permits a user to change his/her vote on a comment and allows the computer system to compensate correctly for that change. Due to this scheme, there will be at most N versions of the same content broadcast at once (but only 1 broadcast per device per content), where N is the number of Client Computers, in accordance with the Bellman-Ford Algorithm, which proves the stability of the system (Bellman, R. (1958). “On A Routing Problem,” Quarterly of Applied Mathematics 16:87-90; Ford, L. R., Jr. (1956) “Network Flow Theory,” Paper P-923. Santa Monica, Calif.: RAND Corporation). Most preferably, in calculating the union of the data, the Client Computer will weight the data by the proximity of the content-providing Client Computers, such that votes cast by proximal users will be counted more heavily than votes cast by more distant users.

Alternatively, data race issues may be resolved without requiring and storing unique user identifier codings. In such a scenario, each Client Computer stores as N_(F), the number of received favorable votes, and as N_(D) the number of received disfavorable votes. When “duplicate” versions of a content are received, or when votes regarding such content is received, the user's Client Computer compares newly received favorable votes with the stored favorable vote tally, and stores the maximum number of favorable votes as N_(F). The Client Computer likewise compares newly received disfavorable votes with the stored disfavorable vote tally, and stores the maximum number of disfavorable votes as N_(D). When the Client Computer then provides such content to other Client Computers, it provides such N_(F) and N_(D) values as well.

Since a distributed network involves the provision of data among potentially large numbers of Client Computers, its bandwidth requirements can increase exponentially with the number of Client Computers and the number of content topics being provided. A further attribute of the computer systems of the present invention are their ability to control such bandwidth requirements. This is preferably accomplished through the formation and use of a “Content Stack.” In this regard, a Client Computer will preferably be limited to providing/re-providing K content per iteration, where K is a positive integer set by the user in light of the processing speed, memory attributes and bandwidth accessibility of his/her Client Computer. When a new content is received, such content is sorted into the Content Stack by its weighting on the receiving Client Computer, and, if necessary due to memory or processing constraints, the least valued content of the Content Stack is dropped from Client Computer's Content Stack. It is preferred that valued content (i.e., content that is presented to the Client Computer's user) be stored separately on a user's Client Computer (e.g., in the Client Computer's Presentation Stack) so that it will not be erroneously removed. Content that exceeds K content per iteration may be provided to other Client Computers, if bandwidth is not limited. Preferably such additional content will be provided only if bandwidth and/or processing capacity are not limiting for, so as to promote dynamic interactions among Client Computers, rather than a “Twitter®”-like, serial interaction (Twitter, Inc.). The Content Stack differs from the Presentation Stack (described below) in size (typically holding more topics than is presented to the user in the Presentation Stack), and content (typically holding content established by the Network, for example in accordance with the Network's General Terms of Service (or in the case of a Restricted Network, in accordance with the Restricted Network's Terms of Service) terms of service, whereas the Presentation Stack holds content in accordance with Client Computer preferences). The Content Stack will preferably store 50, 100, 200, 500, 1000, 5000 or more contents.

In a preferred embodiment, the Client Computers of a computer system of the present invention will store received content in their respective Content Stack memories such that the amount of content (e.g., the number of topics, or the amount of memory allocated to content storage) may vary in response to bandwidth and/or processing capacity. As content fills the Content Stack memory of a Client Computer, the lowest stack contents are pushed down until they fall out of the stack and are no longer disseminated to the network by that Client Computer.

A received content is initially ordered in the Content Stack memory of a receiving Client Computer based upon its “Favorability Value,” (see, e.g., Bardala, V. et al. (2010) “A Novel Learning Based Solution For Efficient Data Transport In Heterogeneous Wireless Networks,” Wireless Networks 16(6):1777-1798; Ramana, B. V. et al. (2008) “A Novel Learning Based Solution for Efficient Data Transport in Heterogeneous Wireless Network,” High Performance Computing—HiPC 2008 Lecture Notes in Computer Science 5374:402-414; Bellavista, P. et al. (2007) “Context-Aware Handoff Middleware For Transparent Service Continuity In Wireless Networks,” Pervasive and Mobile Computing 3(4):439-466) with content having a higher Favorability Value placed above content having a lower Favorability Value.

The Favorability Value of content according to the present invention is determined by a “Favorability Function” (“F_(Favorability)”), which is a function of a set of Favorability Parameter Functions relating to “Favorability Parameters” that the network has elected to consider as relevant to the Favorability Value. Thus, the Favorability Value of a content (e.g., Content N) is determined from the Favorability Function's consideration of Client Computer-selected or network-selected Favorability Parameters relating to such content:

$F_{{Favorability}_{ContentN}} = {f\begin{Bmatrix} {f_{1^{st}{Favorability}\mspace{11mu} {Parameter}}\left( {1^{{st}\mspace{14mu}}{Favorability}\mspace{14mu} {Parameter}} \right)} \\ {f_{2^{nd}{Favorability}\mspace{11mu} {Parameter}}\left( {2^{nd}\mspace{14mu} {Favorability}{\; \mspace{11mu}}{Parameter}} \right)} \\ {f_{3^{rd}{Favorability}\mspace{11mu} {Parameter}}\left( {3^{rd}\mspace{14mu} {Favorability}{\; \mspace{11mu}}{Parameter}} \right)} \\ \vdots \\ {f_{4^{th}{Favorability}\mspace{11mu} {Parameter}}\left( {n^{th}\mspace{14mu} {Favorability}\mspace{14mu} {Parameter}} \right)} \end{Bmatrix}}$

The Favorability Function may be static, or may be updated. Such updates may be in real-time to address network flow and capacity constraints or other network or business/commercial objective(s).

Examples of Favorability Parameter Functions include:

ƒ_(vote) a function of the Favorability Parameter: vote, that weights the number of favorable/disfavorable votes that a content has received; for example, such a function might increase in value as the relative number of favorable votes for a content increases; ƒ_(dissemination) a function of the Favorability Parameter: dissemination, that weights the extent of the content's dissemination across the network (e.g., the number of hops made by such content); for example, such a function might increase in value as the extent of such content's dissemination increases; ƒ_(distance) a function of the Favorability Parameter: distance, that weights the distance between the content originator and the receiving Client Computer; for example, such a function might decrease in value as the distance between the content originator and the receiving Client Computer increases; ƒ_(hop-distance) a function of the Favorability Parameter: hop-distance, that weights the distance between the Client Computer providing such content and the receiving Client Computer; for example, such a function might increase in value as the distance between the content originator and the receiving Client Computer decreases; ƒ_(time) a function of the Favorability Parameter: time, that weights the time interval between the time at which the content was originated and the time at which such content is received by the receiving Client Computer; ƒ_(premium) a function of the Favorability Parameter: premium, that weights the premium enhanced favorability that content may acquire from commercial, governmental, social or other weightings (for example, corporate sponsorship of a content, advertising, emergency warnings, etc.); and ƒ_(segment) a function of the Favorability Parameter: segment, that presents content meeting network-selected “segmenting” criteria. For example, content may be segmented to provide higher weight to content being disseminated (or favorably voted upon) by users of (or for) a certain age (e.g., children, the elderly, young adults, etc.), and/or by users having a certain income level or income threshold, and/or by users at a particular timedate (e.g., today, yesterday, a week or month ago, 2 hours earlier, etc., or at a particular selected time, e.g., Mar. 1, 2018 at 16:00 PST), and/or by users at a selected location (when accessing the content), and/or by users of a selected locality (home region), and/or by users of a selected identification (gender, ethnicity, race, locality, etc.). The present invention envisions the use of these, and/or any other, desired segmenting criteria in any combination or permutation. Thus, example, the network could for employ an ƒ_(segment) Favorability Parameter Function to identify content of interest to young girls, retired male senior citizens, French-speaking children, exotic car owners, etc. such that an illustrative Favorability Function for a Content N would be:

$F_{Favorability} = \begin{Bmatrix} {f_{vote}\begin{pmatrix} {{Number}\mspace{14mu} {of}\mspace{14mu} {Favorable}\mspace{14mu} {Votes}} \\ {{Received}\mspace{14mu} {by}\mspace{14mu} {Content}\mspace{14mu} N} \end{pmatrix}} \\ {f_{dissemination}\begin{pmatrix} {{Number}\mspace{14mu} {of}\mspace{14mu} {Clients}\mspace{14mu} {Disseminating}} \\ {{Content}\mspace{14mu} N} \end{pmatrix}} \\ {f_{distance}\mspace{11mu} \begin{pmatrix} {{Distance}\mspace{14mu} {from}\mspace{14mu} {Content}\mspace{14mu} N\mspace{14mu} {Origination}\mspace{14mu} {to}} \\ {{Receiving}\mspace{14mu} {Client}\mspace{14mu} {Computer}} \end{pmatrix}} \\ {f_{{hop} - {distance}}\mspace{11mu} \begin{pmatrix} {{Distance}\mspace{11mu} {of}\mspace{14mu} {Hop}\mspace{14mu} {from}\mspace{14mu} {Providing}\mspace{14mu} {Client}} \\ {{to}\mspace{20mu} {Receiving}\mspace{14mu} {Client}\mspace{14mu} {Computer}} \end{pmatrix}} \\ {{f_{time}\begin{pmatrix} {{Time}\mspace{14mu} {Interval}\mspace{14mu} {from}\mspace{14mu} {Content}\mspace{14mu} N\mspace{14mu} {Origination}} \\ {\begin{matrix} {{to}\mspace{14mu} {Time}\mspace{14mu} {of}\mspace{14mu} {Receipt}\mspace{14mu} {by}} \\ {\; {{Receiving}\mspace{14mu} {Client}\mspace{14mu} {Computer}}} \end{matrix}\mspace{11mu}} \end{pmatrix}}{\mspace{14mu} \mspace{11mu}}} \\ {f_{premium}\begin{pmatrix} {{Premium}\mspace{14mu} {Favorability}\mspace{14mu} {Enhacement}} \\ {{of}\mspace{14mu} {Content}\mspace{14mu} N} \end{pmatrix}} \\ {f_{segment}\begin{pmatrix} {{Segementing}\mspace{14mu} {Criterion}\text{/}{Criteria}\mspace{14mu} {Selected}} \\ {{by}\mspace{14mu} {User}\mspace{14mu} {or}\mspace{14mu} {Network}} \end{pmatrix}} \\ {\mspace{85mu} \begin{bmatrix} {f_{age}\left( {{Age}\mspace{14mu} {of}\mspace{14mu} {User}} \right)} \\ {\mspace{25mu} {f_{income}\left( {{Income}\mspace{14mu} {of}\mspace{14mu} {User}} \right)}} \\ {\mspace{34mu} {f_{timedate}\left( {{TimeDate}\mspace{14mu} {of}\mspace{14mu} {User}\mspace{14mu} {Vote}} \right)}} \\ {\mspace{56mu} {f_{location}\left( {{Location}\mspace{14mu} {of}\mspace{14mu} {User}} \right)}} \\ {\mspace{79mu} {f_{locality}\left( {{Locality}\mspace{11mu} {of}\mspace{14mu} {User}} \right)}} \\ {\mspace{95mu} {f_{identification}\left( {{Identification}\mspace{14mu} {of}\mspace{14mu} {User}} \right)}} \\ {\mspace{135mu} \vdots} \\ {\mspace{124mu} {{f_{segment}}_{n}\left( {{Segment}\mspace{14mu} {Criterion}\mspace{14mu} n} \right)}} \end{bmatrix}} \\ {\mspace{40mu} \vdots} \\ f_{n} \end{Bmatrix}$

The Favorability Parameter Functions employed in a Favorability Function may independently be linear, logarithmic, exponential, etc. For example, an ƒ_(vote) function might be applied to a content such that the function's value for such content would increase linearly or exponentially in response to increasing numbers of favorable votes, thereby increasing its dissemination. An ƒ_(dissemination) function might be applied to a content such that the function's value for such content would increase linearly or exponentially in response to the extent of the content's dissemination across the network, but then decrease so as to allow new content to traverse the network. An ƒ_(distance) function might be employed that would apply an inverse linear function, or a negative exponential function, to content, such that the function's value for such content would decrease to reflect the distance between the content originator and a receiving Client Computer. An ƒ_(hop-distance) function might be applied to a content such that the function's value for such content could increase linearly or exponentially as the distance between the content originator and the receiving Client Computer decreases, but then level off or decrease for content having short hop distances or substantially unchanging hop distances. An ƒ_(time) function might be applied to a content such that the function's value for such content would increase, possibly rapidly (e.g., linearly or exponentially), but then level off or decrease over time (e.g., inverse linear, negative exponential, logarithmic, etc., so as to foster the dissemination of new content and the non-dissemination of older content. An ƒ_(premium) function might be applied to a content in order to “outweigh” completely or partially, other Favorability Parameter Functions. As will be recognized, by selection of Favorability Parameters, and Favorability Parameter Functions, the present invention permits the Favorability Function to be set and fine-tuned to address bandwidth and issues of network flow.

An ƒ_(segment) function might be applied to content in order to present to a user content being disseminated that has been judged (e.g., by the Network or by other users) to be of particular interest to children, the elderly, those having a certain income level, etc. The function may be applied to past or current network traffic to assess and evaluate what content had been, or is currently being, judged most relevant (e.g., most favorably) or least relevant (e.g., least favorably) by selected market segments of users (e.g., by population, age, income, ethnicity, etc.). In the most preferred embodiment, user information, such as age, income, identification, etc. would be anonymously provided and be derived from the user's profile or preferences as entered into and stored on the user's Client Computer.

Thus, as (or if) a particular content is re-received by a Client Computer, the position of that content in the Content Stack memory of such Client Computer may change to reflect the updated Favorability Value of that content on the network. For example, re-received content that is found to have acquired a higher (or lower) Favorability Value but which has had less dissemination can be accorded a higher Content Stack position than such content would have been accorded had it had greater dissemination. The Favorability Function ensures that a content converges (i.e., does not “crisscross” indefinitely (and exponentially) across the network until it consumes all bandwidth). As the extent of its dissemination increases, the function causes the Favorability Value of a content to decrease until it ultimately falls from the Content Stack memory.

Thus, in sum, content stored in Content Stack memory rises in response to increases in the Favorability Value of the content, and falls in the Content Stack memory in response to decreases in its Favorability Value, such that the number or amount of content stored in the Content Stack memory and provided to other Client Computers of the network remains within available processing and bandwidth parameters. Such parameters may additionally use an ƒ_(premium) Favorability Parameter Function to prioritize (i.e., overweight) content received by a Client Computer that is provided by sponsors (e.g., commercial sponsorships, advertisements, etc.) or from a Restricted Computer Network, such that such sponsored content or such received Restricted Computer Network content may be preferentially provided to other Client Computers and thus preferentially disseminated across the distributed network.

Consistent with the above exposition, the invention encompasses any combination of Favorability Parameters. However, it is preferred that Favorability Value is determined by a Favorability Function that considers one or more Favorability Parameter(s), with the proviso that when selected Favorability Parameters include both vote and time, the Favorability Function shall additionally consider one or more additional Favorability Parameter(s).

Preferably, a Client Computer of a computer system of the present invention will select from the received content of its Content Stack memory, valued or desired content that is to be presented to the user of that Client Computer. Such valued or desired content will preferably be stored in the Client Computer's memory in a “Presentation Stack” memory, such that the amount of content (e.g., the number of topics, or the amount of memory allocated to content storage) is user-controlled and varies in response to user-selected parameters (such as a user's content weighting preferences) and received new content. Content stored in Presentation Stack memory is preferably determined by the proximity between the content-receiving Client Computer and a content-providing Client Computer that is providing such content, by the Favorability Value of the content and by the weighting preferences being applied by the content-receiving Client Computer, such that the number or amount of content stored in the Presentation Stack memory of the Client Computer remains within user-selected parameters. A Client Computer of the present invention may have a single Presentation Stack memory, or may have 2, 3 or more than 3, separate Presentation Stacks memory. For example, content in a “first” language may be stored in a “first” Presentation Stack memory, and content in a “second” language may be stored in a “first” Presentation Stack memory.

Content stored in Presentation Stack memory thus:

-   -   (A) rises in the Presentation Stack memory in response to:         -   (1) increased proximity between the content-receiving Client             Computer and a content-providing Client Computer that is             providing such content;         -   (2) increases in the Favorability Value of the content; and         -   (3) changes in the weighting preferences applied by the             content-receiving Client Computer that increase the user's             desire for such content; and     -   (B) falls in the Presentation Stack memory in response to:         -   (1) decreased proximity between the content-receiving Client             Computer and a content-providing Client Computer that is             providing such content;         -   (2) decreases in the Favorability Value of the content; and         -   (3) changes in the weighting preferences applied by the             content-receiving Client Computer that decrease the user's             desire for such content;     -   such that the number or amount of content stored in the         Presentation Stack memory of the Client Computer remains within         user-selected parameters.

It will be understood that although for ease of reference, the present invention refers to such memory as “stacks,” the term is intended to generally encompass and denote a database of any structure in which a particular content is associated with such proximity, Favorability Value and weighting preferences.

Most preferably new topics (i.e., topics that were not previously provided to a Client Computer) comporting with the weighting preferences of the user will be initially placed at the top of the Presentation Stack upon their receipt, pending a user-provided vote to favor or disfavor such content. The Presentation Stack will preferably store the 1, 5, 10, 20, 50, 100, etc. most discussed topics received by the Client Computer.

Although the Content Stack and Presentation Stack may be separately stored, it is preferable to combine both stacks to form a single memory stack that internally distinguishes presented content from other stored content.

FIGS. 3A-3B illustrate how the memory stacks of two Client Computers (Client Computers 1 of User A and Client Computer 2 of User B) change in response to the sharing of their content. As illustrated in FIG. 3A, both Client Computers have been instructed to display only 5 topics (i.e., their Presentation Stacks are both set to display only the most valued or desired 5 contents). Content from Client Computer 1 is provided to Client Computer 2, but, in accordance with User B's instructions, Client Computer 2 only presents topics that have been weighted. Non-presented content is preferably stored in Client Computer 2's memory (shown grayed in FIG. 3A) so that it may be readily presented to User B should User B's weighting preferences change. Likewise, content from Client Computer 2 is provided to Client Computer 1, and topics are presented to User A in accordance with User A's weighting preferences, and non-presented content is preferably stored in Client Computer 1's memory (shown grayed in FIG. 3A) so that it may be readily presented to User A should User A's weighting preferences change. FIG. 3B illustrates how the respective stacks of Client Computer 1 and Client Computer 2 are changed by content sharing between them. New content is added to the top of the stack, and existing content is repositioned in the stack, or dropped from the presented content of the stack, reflecting the respective user's weighting preferences.

Each favorable vote received by a particular content enhances its rank-weighting and thus its ability to flow across the network. Likewise, receipt of disfavoring votes diminishes the rank-weighting of the content, and thus decreases its ability to flow across the network. Thus, content having higher favorable votes will flow further than content having higher disfavorable votes. As discussed above, a Client Computer may be configured to present its user with content pertaining to the 1, 5, 10, 20, 50, 100, etc. most discussed topics received by the Client Computer. As a particular content receives additional disfavorable votes (or as other content receive additional more favorable votes), such particular content will fall in ranking until it is eventually dropped from the stack of content presented to the user or saved by the Client Computer.

Preferably, the vote associated with a particular content and the physical distance between a content-providing Client Computer and a content-receiving Client Computer will be used in determining whether to present the content to the content-receiving Client Computer's user. Accordingly, if the distance from the content-providing Client Computer to the content-receiving Client Computer is further than the rank-weight of a content, the content may be dropped and not added to the content-receiving Client Computer's content.

As illustrated in FIG. 4A, content provided by distant users may not be as relevant as content of proximal users. The proximity-weighting attribute of the present invention (discussed below) permits Client Computers that are positionally located in proximity to one another to exchange and share content, thereby providing a more relevant presentation of content (FIG. 4B).

Any user, however, may use keywords (i.e., query-weighting), such that content relevant to such topics will receive a higher ranking and be retained by the recipient's Client Computer. For example, if a User A provides content “apple” having a vote of +10 to Users B and C located 10 km away, the content may be dropped by the Client Computer of User B (and thus not be presented to User B); User B's Client Computer's stack of content will be adjusted accordingly to present content of higher ranking. However, if User C has set a query-weighting for “apple,” then the content will not be dropped by the Client Computer of User C (and thus will be presented to User C). Thus, the weighting that determines whether received content will be presented/provided to other Client Computers (or, alternatively, dropped) preferably depends upon the relative locations of the providing and content-receiving Client Computers and the union of vote data of that content, as calculated by the content-receiving Client Computer, taking into account any user-provided topic-weighting or query-weighting instructions. The ability of a particular content to be shared among all members of a network depends upon the ranking of such content, the distance between Client Computers, and the ranking of other content that may be provided to a recipient Client Computer. Thus, whereas the computer systems of the present invention have the ability to distribute a particular content to all Client Computers of the network, the systems (and/or individual Client Computers thereof) also possess the ability to limit the distribution of content in accordance with user-selected or system-determined weighting option(s).

B. Operation of a Preferred Non-Distributed Computer Systems of the Present Invention

The computer systems of the present invention may be established as a non-distributed computer system, such as a centralized or regionalized computer system. In such an embodiment, individual Client Computers provide a central or regional server with their respective user identifier coding, Client Computer identifier coding, positional location and weighting preferences. Content, and any votes relating to such content, are provided to the server, which then establishes a centralized database capable of being accessed by individual Client Computers and of presenting to such Client Computers received content that has been weighted according to each such Client Computer's respective proximity and other weighting preferences.

The use of a non-distributed computer system eliminates the possibility of a data race, but entails interconnectivity (and preferably, real-time interconnectivity) between individual Client Computers and a remote, and possibly distant, server.

IV. Open Computer Networks and Restricted Computer Networks

The distributed or non-distributed networks of the present invention may be configured as a single Open Computer Network or as comprising one, two, three or more Restricted Computer Network(s). The computer network of the present invention may alternatively be configured to comprise both a single Open Computer Network and also such one, two, three or more Restricted Computer Network(s).

As used herein, an “Open Computer Network” is one that any Client Computer in communication range will be eligible to join, either automatically, or more preferably, upon the request of the entering Client Computer and subject to its user's agreement to General Terms Of Service. As used herein, terms of service are said to be “General Terms Of Service” if they are not specific to particular users but are required of all users within communication range. Such General Terms Of Service could include, for examples, restrictions on the provision of copyrighted materials, agreement to permit other Client Computers to copy received content and provide such content to additional Client Computers, restrictions on use, restrictions on the nature of content that may be provided, etc.)

In contrast, a “Restricted Computer Network” is one in which any Client Computer in communication range will be eligible to join, either automatically, or more preferably, upon the request of the entering Client Computer, subject to agreement to Restricted Computer Network Terms Of Service. As used herein, terms of service are said to be “Restricted Computer Network Terms Of Service” if they are specific to a particular Restricted Computer Network. For example, such Restricted Computer Network Terms Of Service may require confidentiality or require the provision of authentication credential(s) (e.g., a password (textual, image, tonal, digital key, etc.) or biometric credential (such as a fingerprint, face recognition match, DNA match, palm print, hand geometry match, iris recognition match, retinal pattern match, odor/scent match, typing rhythm, gait, voice pitch/accent, voice recognition pattern, etc.) that is selected by and associated with such Restricted Computer Network.

Preferably, although only those Client Computers that have been authenticated and accepted to a Restricted Computer Network will be able to receive content provided by other Client Computers of the Restricted Computer Network, all Client Computers within communication range of such an accepted Client Computer will be able to provide content to Client Computers of the Restricted Computer Network. Thus, both authenticated and non-authenticated Client Computers assist in disseminating Restricted Computer Network content among the authenticated Client Computers of the Restricted Computer Network, even though such content would not be perceivable by the users of the non-authenticated Client Computers. Less preferably, only Restricted Computer Network authenticated Client Computers will be able to provide such Restricted Computer Network content to other authenticated Client Computers.

Client computers of a Restricted Computer Network may provide and receive “encrypted” content, which may then be decrypted by other Client Computers of the Restricted Computer Network. For example, content may be encrypted using an AES (128, 192, or 256 bit), a Triple DES (2-key or 3-key), a CASTS (80 or 128 bit) encryption algorithm, etc. and an associated encryption key (e.g., an RSA key, a Diffie-Hellman key, an MQV key, a key produced through an Elliptic Curve algorithm, etc.), which is possessed by Client Computers of such Restricted Computer Network. Alternatively, a Restricted Computer Network may provide and receive non-encrypted content.

When the computer system of the present invention comprises more than one network, the selection of which network is to be used by a content-providing Client Computer may be established by the Client Computer's user, or may be established by the General Terms Of Service (for an Open Computer Network) or the such Restricted Computer Network Terms Of Service (for one or more Restricted Computer Networks). Alternatively, network selection may be determined heuristically based upon a user's prior network selection(s). Alternatively, content received from a particular joined network will automatically configure the receiving Client Computer to provide responding content using the same network, whether open or restricted, unless changed by the Client Computer's user.

Preferably, however, a Client Computer that has joined an Open Computer Network and one or more of such additional Restricted Computer Networks will provide its user with the option of providing content on any of such joined networks via, for example via the use of a “Network Selection Signal” (NSS). The Network Selection Signal may be an actual button, switch, slide, etc., or may be a screen icon of such a button, switch, slide, etc., or other signal or indication recognized by the Client Computer. The Network Selection Signal may alternatively be configured as a Client Computer orientation, a Client Computer movement (e.g., a “shaking” movement), a voice command, a sound, light or an image recognition etc.). Preferably the employed Network Selection Signal will allow users to easily, rapidly and assuredly select a desired network for providing content to others. Preferably, the Client Computer will provide its user with a feedback signal or other indication indicating which network is to be employed for content provision.

Whereas the provision of the Open Computer Networks of the present invention has particular utility in social media and proximity-based mass communication, the provision of the Restricted Computer Networks of the present invention, particularly if configured as a distributed computer network, has particular utility in enhancing the coordination and security of police, firefighters and other emergency responders. For example, a Restricted Computer Network that is available to first responders at an emergency site allows police, firefighters and other emergency personnel to communicate with one another without being tethered to a centralized server. Instead, network content would “hop” from one responder's Client Computer to another responder's Client Computer. Thus, the effective communication range would extend from the on-site command and control center to the most distant of the responders (see, FIG. 1). Moreover, since access to the content is restricted to authenticated Client Computers, information communicated between responders would be secure and confidential. Additionally, because the preferred computer network will also comprise an Open Computer Network, first responders will be able to communicate with civilians and victims, separately from any communications with other first responders. An exemplary set of communications among the first responders relating to a fire scene is shown below in Table 1. In Table 1, the firefighters have Client Computers that are joined to the open (“O”) network (thereby enabling their users to communicate with victims and non-emergency response personnel whose Client Computers are also joined to the open (“O”) network. Additionally, the firefighters are joined to a restricted “Fire Responders” (“FR”) network. The Restricted Computer Network Terms Of Service of the FR network defaults provided content to the FR network and require firefighters to provide a Network Selection Signal (“NSS”) in order to provide content to another network. Thus, as shown in Table 1, firefighters provide an NSS of “O” in order to provide content over the Open Computer Network. The general network terms of service of the open (O) network presumes that content is to be provided over the Open Computer Network and thus does not require any NSS signaling of the network to be employed. The content shown in Table 1 is shown as textual for ease of representation, but may be audio, image, video, etc., as discussed above.

TABLE 1 Content Content Msg Ntwk Provider NSS Provided Content Receivers 1 R Fire None “Fire is spreading to All first Team 1 Needed the third floor! responders, Bring more hoses!” but no others 2 O Fire O “Is anyone trapped All first Team 1 in here?” responders, and all others 3 O Victim 1 None “Help me! I'm John. All first Needed I'm on the third floor!” responders, and all others 4 R Command None “Fire Team 1, we are All first Center Needed sending additional responders, personnel to help John. but no Stay where you are and others fight the fire.” 5 R Fire None “Acknowledged; All first Team 1 Needed we will fight the responders, fire from here.” but no others 6 O Fire O “John, stay where All first Team 1 you are. Help is responders, on the way.” and all others 7 O Victim 1 None “OK” Needed 8 R Fire None “We have John. He is All first Team 2 Needed injured. We will evacuate responders, him. Have an ambulance but no standing by!” others Msg denotes Message Number Ntwk denotes Network. R denotes content provided/received on a Restricted Computer Network. O denotes content provided/received on an Open Computer Network.

Significantly, due to the ability of the individual Client Computers of the first responders to both receive and provide content, Message 1 is relayed from Client Computer to Client Computer and is received by the Command Center at substantially the same time as it is provided by Fire Team 1. Additionally, Message 3 is received from Victim 1 at the Command Center automatically, and at substantially the same time as it is received by Fire Team 1. Thus, information regarding Victim 1 is received at the Command Center without any active intervention by Fire Team 1. The decision to delay the rescue of Victim 1 until Fire Team 2 is in position (Message 4) may reflect the existence of other victims or extenuating circumstances having higher priority. In order to prevent panic and to allow the firefighters to more effectively triage the emergency response, Message 4 is therefore provided over the Restricted Computer Network and is thus not perceivable by Victim 1. All first responders simultaneously learn of the successful rescue of Victim 1 through Message 7.

The use of the Restricted Computer Network of the present invention, particularly if configured as a distributed computer network, likewise has particular utility in enhancing the coordination and security of soldiers and other military personnel engaged in military operations. The distributed configuration of the network permits its range to extend from the most advanced soldier to that soldier's command and control center. Content provided to the Restricted Computer Network is immediately provided to all Client Computers that have joined the Restricted Computer Network, thus facilitating communication between soldiers and soldiers and their command centers. As discussed above, the present invention contemplates computer networks that comprise multiple Restricted Computer Networks. Thus, it is possible to share information with only a subset of a force (e.g., officers, advance troops, corpsmen, supply teams, intra-squad, between nearby squads, global watchers, etc.).

The use of the Restricted Computer Network of the present invention, particularly if configured as a distributed computer network, similarly has particular utility in enhancing the coordination and security of private businesses. The distributed configuration of the network permits its range to extend across the entire facility of a business. Content provided to the Restricted Computer Network is immediately provided to all Client Computers have joined the Restricted Computer Network, thus facilitating communication between individuals having shared responsibilities. As discussed above, the present invention contemplates computer networks that comprise multiple Restricted Computer Networks. Thus, it is possible to share information with only a subset of a business' personnel (e.g., management, shipping, sales, security, etc.).

V. Content Weighting and the Presentation of Weighted Content

As discussed above, the distributed or non-distributed networks of the present invention serve to disseminate content among Client Computers that are joined to such networks. One aspect of the present invention relates to the ability of the Client Computers to restrict and/or filter received content in order to present to its user content that is weighted according to the user's preferences. Thus, for purposes of illustration, the Client Computer may be directed to present content that is proximity-weighted, rank-weighted, topic-weighted, query-weighted, time-weighted, location-weighted, locality-weighted, vote-weighted, segment-weighted and/or geophysically-weighted. Any combination of such illustrative weighting preferences, and/or of other weighting preferences, may be employed.

As used herein, the term “proximity-weighted” is intended to denote that a Client Computer is to “weight” (i.e., filter, order, array, etc.) the content that is to be presented to such Client Computer's user so that it is ranked according to the proximity of the content-providing Client Computer to the locational position of the content-receiving Client Computer. Thus, for example, a Client Computer applying proximity-weighting to received content would present its user with content about topics being discussed within 5 meters of the content-receiving Client Computer's location, within 10 meters of the content-receiving Client Computer's location, within 25 meters of the content-receiving Client Computer's location, within 50 meters of the content-receiving Client Computer's location, within 100 meters of the content-receiving Client Computer's location, within 250 meters of the content-receiving Client Computer's location, within 500 meters of the content-receiving Client Computer's location, within 1 kilometer of the content-receiving Client Computer's location, within 5 kilometers of the content-receiving Client Computer's location, within 10 kilometers of the content-receiving Client Computer's location, within 25 kilometers of the content-receiving Client Computer's location, within 50 kilometers of the content-receiving Client Computer's location, within 100 kilometers of the content-receiving Client Computer's location, or within a larger distance from the content-receiving Client Computer's location. A user of such proximity-weighting would then be able to perceive the most frequently commented topics within his/her vicinity.

As used herein, the term “rank-weighted” is intended to denote that a Client Computer is to weight the content that is to be presented to such Client Computer's user so that it is ranked according to the amount of related content (relative to all content) received by the Client Computer. Thus, for example, a Client Computer applying rank-weighting to received content would present its user with content pertaining to the 1, 5, 10, 20, 50, 100, etc. most discussed topics received by the Client Computer. A user of such rank-weighting would then be able to perceive the most frequently commented topics provided to the Client Computer.

As used herein, the term “topic-weighted” is intended to denote that a Client Computer is to weight the content that is to be presented to such Client Computer's user so that it is ranked according to content “topic” (e.g., a name, event, subject, person, occurrence, etc.). Thus, for example, a Client Computer applying topic-weighting to received content would present its user with related content for an alphabetically sorted list of topics received by the Client Computer. A user of such topic-weighting would then be able to perceive content relevant to one or more particular topics of interest.

As used herein, the term “query-weighted” is intended to denote that a Client Computer is to weight the content that is to be presented to such Client Computer's user so that it is ranked according to its perceived relevance to search queries (keywords, images (which may be user-perceivable, e.g., a photograph, etc., or may be machine-readable, e.g., a barcode, data matrix, Aztec code, QR code, etc.), video, sounds (e.g., a recorded voice, sound, music, etc.) provided by the user. Thus, for example, a Client Computer applying a query-weighting to received content would present its user with content pertaining to a particular interest of the user (e.g., a name, event, subject, person, occurrence, etc.). A user of such query-weighting would then be able to perceive content relevant to particular topics satisfying the query. A single query or multiple queries may be simultaneously applied. Multiple queries may be applied disjunctively (e.g., “weather” or “Seattle”) or conjunctively (e.g., “weather” and “Seattle”). Queries may employ Boolean connectors (e.g., and, not, or, near, when, where, etc.). By querying an image or sound (e.g., a photograph of a particular child, or the sound of that child's voice), a user would be able to use interconnected Client Computers to locate the image or sound (e.g., to find the child) if present or perceivable on the network. Similarly, by querying for content in a particular user-selected language (e.g., wherein the language of a text, sound, or video, etc. or the language of text presented in an image, etc., is a particular user-selected language), a user would be able to use interconnected Client Computers to locate content that had been provided in such language. Thus, for example, a user could access content relating to “weather” in “Seattle” in “German.” Thus, whereas topic-weighting presents a user with a list of topics received by the user's Client Computer, query-weighting presents a user with a list of topics of particular relevance to such user.

As used herein, the term “time-weighted” is intended to denote that a Client Computer is to weight the content that is to be presented to such Client Computer's user so that it is ranked according to its recency. Thus, for example, a Client Computer applying time-weighting to received content would present its user with related content for a list of the 1, 5, 10, 20, 50, 100, etc. most recent topics provided to the Client Computer, or topics arising within the most recent 10 minutes, 30 minutes, hour, day, week, month, year, etc. A user of such time-weighting would then be able to perceive the most recent content presented to the Client Computer.

As used herein, the term “location-weighted” is intended to denote that a Client Computer is to weight the content that is to be presented to such Client Computer's user so that it is ranked according to a user-selected place or location. Thus, for example, a Client Computer applying a location-weighting to received content would present its user with content pertaining to a particular area, such as a college or university campus, a neighborhood, an event locale (e.g., an amusement park, a fair, a cruise ship, a conference, etc.), a city, a state, a country, a sub-continental region (e.g., Northern Europe, the Middle East, etc.), or a continent. Such location-weighting may be used to identify users who are located, for example, within 100 kilometers of a predefined position, within 50 kilometers of such predefined position, within 25 kilometers of such predefined position, within 10 kilometers of such predefined position, within 5 kilometers of such predefined position, within 1 kilometer of such predefined position, within 10 kilometers of such predefined position, within 5 kilometers of such predefined position, within 1 kilometer of such predefined position, within 500 meters of such predefined position, within 250 meters of such predefined position, within 100 meters of such predefined position, within 50 meters of such predefined position, within 25 meters of such predefined position, within 10 meters of such predefined position, within 5 meters of such predefined position, etc. A user of such location-weighting would then be able to perceive content involving such location, including the number and positions of Client Computer users at such location. In one embodiment, such location information would be ranked by distance (e.g., so as to identify the Client Computer user of the nearest neighbor, or to identify the number and/or identities of other Client Computer users that are within a provided distance from a user's Client Computer. In one embodiment, such location information would be anonymous (i.e., the identities of the located users would not be revealed). Alternatively, particularly with restricted networks, such location information could additionally reveal the identities of the located users.

As used herein, the term “locality-weighted” is intended to weight the content that is to be presented to such Client Computer's user so that it is ranked according to a user's home region. Thus, for example, a Client Computer applying a location-weighting to received content would present its user with content pertaining to a user's hometown, county, state, etc. irrespective of the user's current location.

As used herein, the term “vote-weighted” is intended to denote that a Client Computer is to weight the content that is to be presented to such Client Computer's user so that it is ranked according to the percentage of favorable votes received (relative to all received votes) that such content has received from other users whose Client Computers have previously received such content and whose users have voted their responses or reactions to such content. Thus, for example, a Client Computer applying vote-weighting to received content would present its user with content that had received a vote of greater than 50% favorable votes, greater than 60% favorable votes, greater than 70% favorable votes, greater than 80% favorable votes, greater than 90% favorable votes, greater than 95% favorable votes, etc. A user of such vote-weighting would then be able to perceive the most liked commented topics provided to the Client Computer.

As used herein, the term “segment-weighted” is intended to denote that a Client Computer (or, as discussed below, a Content-Monitoring Computer of, or accessing, the network) is to weight content that is to be presented to such computer's user so that it is ranked according to one or more of the network-set segment criteria (e.g., age of other users, income of other users, timedate (day, date or time in which other users accessed the content), location of other users when accessing the content, locality (home region) of other users, identification (gender, ethnicity, race, locality, language, etc.) of other users, etc. The present invention envisions the use of these, and/or any other, desired segmenting criteria in any combination or permutation. Thus, to illustrate, the client or other network-accessing computer could assess and present content of interest to young girls, retired male senior citizens, French-speaking women, exotic car owners, etc. Segment-weighting is thus similar to query-weighting, but differs in that the segments available for segment-weighting are established by the network, whereas the queries available for query-weighting are established individually by the Client Computers.

As used herein, the term “geophysically-weighted” is intended to denote that a Client Computer is to weight the content that is to be presented to such Client Computer's user so that it is ranked according to one or more geophysical attribute(s) (e.g., ground movements, atmospheric data (such as barometric pressure, air temperature, wind velocity, wind direction, precipitation amount, precipitation type, etc.), hydrologic data (such as water temperature, wave height, wave velocity, etc.), fire locations or boundaries (e.g., wild-fires, etc.) or other weather information, so as to be capable of presenting such data to a user. Particularly in conjunction with location-weighting, the presentation of geophysically-weighted content permits the user interface to comprise a map (such as a “heat map,” street map, flight path map, etc.) capable of indicating the number and position of Client Computer users who may be located in the path of an oncoming geophysical event (e.g., storm, tornado, hurricane, blizzard, fire, etc.), and can thereby facilitate the rescue or evacuation of such users.

A weighting preference may be applied solely, so as to present a user with content that has been weighted using only 1 weighting preference. More preferably, at the request of a user, a Client Computer may be directed to simultaneously apply any 2, any 3, any 4, any 5, any 6, any 7, any 8, any 9, or 10 or more weighting preferences, so as to present the user with desired content. The invention thus permits the presentation of content that has been weighted using:

-   A. only 1 weighting preference, for example, only     proximity-weighting, or only rank-weighting, or only     topic-weighting, etc. (for example to provide a Client Computer with     the most proximal 1, 2, 5, 10, 20, 50, 100, etc. topics,     irrespective of their ranking, topic, recency or location); or -   B. 2 weighting preferences, for example, any of the 45 different     2-membered subsets of the above-described ten illustrative weighting     factors (e.g., proximity-weighting and rank-weighting; or     topic-weighting and locality-weighting, or location-weighting and     segment-weighting; etc.); or -   C. 3 weighting preferences, for example, any of the 120 different     3-membered subsets of the above-described ten illustrative weighting     factors (e.g., proximity-weighting and rank-weighting and     topic-weighting; or time-weighting and location-weighting and     geophysically-weighting; or rank-weighting and query-weighting and     segment-weighting; etc.); or -   D. 4 weighting preferences, for example, any of the 210 different     4-membered subsets of the above-described ten illustrative weighting     factors (e.g., proximity-weighting and rank-weighting and     topic-weighting and query-weighting; or rank-weighting and     topic-weighting and query-weighting and time-weighting; or     topic-weighting and query-weighting and location-weighting and     locality-weighting, etc.); or -   E. 5 weighting preferences, for example, any of the 252 different     5-membered subsets of the above-described ten illustrative weighting     factors (e.g., proximity-weighting and rank-weighting and     topic-weighting and query-weighting and time-weighting; or     rank-weighting and topic-weighting and query-weighting and     location-weighting and geophysically-weighting; or     location-weighting and locality-weighting and vote-weighting and     segment-weighting and geophysically-weighting; etc.); or -   F. 6 weighting preferences, for example, any of the 210 different     6-membered subsets of the above-described ten illustrative weighting     factors (e.g., proximity-weighting and rank-weighting and     topic-weighting and query-weighting and time-weighting and     location-weighting; or rank-weighting and topic-weighting and     query-weighting and location-weighting and vote-weighting and     segment-weighting; or time-weighting and location-weighting and     locality-weighting and vote-weighting and segment-weighting and     geophysically-weighting; etc.); or -   G. 7 weighting preferences, for example, any of the 120 different     7-membered subsets of the above-described ten illustrative weighting     factors (e.g., proximity-weighting and rank-weighting and     topic-weighting and query-weighting and time-weighting and     location-weighting and locality-weighting; or rank-weighting and     topic-weighting and query-weighting and time-weighting and     location-weighting and vote-weighting and segment-weighting; or     topic-weighting and time-weighting and location-weighting and     locality-weighting and vote-weighting and segment-weighting and     geophysically-weighting; or query-weighting and time-weighting and     location-weighting and locality-weighting and vote-weighting and     segment-weighting and geophysically-weighting; etc.); or -   H. 8 weighting preferences, for example, any of the 45 different     8-membered subsets of the above-described ten illustrative weighting     factors (e.g., proximity-weighting and rank-weighting and     topic-weighting and query-weighting and time-weighting and     location-weighting and locality-weighting and vote-weighting; or     rank-weighting and topic-weighting and query-weighting and     time-weighting and location-weighting and locality-weighting and     segment-weighting and geophysically-weighting; or topic-weighting     and query-weighting and time-weighting and location-weighting and     locality-weighting and vote-weighting and segment-weighting and     geophysically-weighting; etc.); or -   I. 9 weighting preferences, for example, any of the 10 different     9-membered subsets of the above-described ten illustrative weighting     factors (e.g., proximity-weighting and rank-weighting and     topic-weighting and query-weighting and time-weighting and     location-weighting and locality-weighting and vote-weighting and     segment-weighting; or proximity-weighting and topic-weighting and     query-weighting and time-weighting and location-weighting and     locality-weighting and vote-weighting and segment-weighting and     geophysically-weighting; or rank-weighting and topic-weighting and     query-weighting and time-weighting and location-weighting and     locality-weighting and vote-weighting and segment-weighting and     geophysically-weighting; etc.); or -   J. 10 weighting preferences, for example, each of the     above-described ten illustrative weighting factors (e.g.,     proximity-weighting and rank-weighting and topic-weighting and     query-weighting and time-weighting and location-weighting and     locality-weighting and vote-weighting and segment-weighting and     geophysically-weighting; etc.); or -   K. More than 10 weighting preferences, for example, any 1-10 of the     above-described ten illustrative weighting factors in combination     with one or more additional weighting factors to provide more than     10 such weighting factors (e.g., proximity-weighting and     rank-weighting and topic-weighting and query-weighting and     time-weighting and location-weighting and locality-weighting and     vote-weighting and segment-weighting and geophysically-weighting and     one or more additional weighting preferences; or proximity-weighting     and rank-weighting and topic-weighting and query-weighting and     time-weighting and location-weighting and locality-weighting and     vote-weighting and geophysically-weighting and two or more     additional weighting preferences, etc.).

By simultaneously applying multiple weighting preferences, a Client Computer can, for example, present to its user related content of the top 1, 2, 5 10, etc. topics being discussed in a room (currently or at a prior user-selected time), or the current (or prior) topics of interest trending in a particular city, etc. Thus, for example, the invention permits attendees of a conference to share content related to topics arising at the conference, or permits individuals interested in being aware of news affecting a region area to be able to determine the most important or latest topics pertaining to such region. The architecture and configuration of the computer system permits the top trending topics to vary as attendees move around the conference, consistent with local variation in the topic rankings. Similarly, individuals concerned about a weather or traffic event may communicate with one another using the present invention.

The Client Computer will preferably permit its user to respond to content provided by other users, so as to permit a content “conversation.” The Client Computer will also preferably permit a user to register a vote as to whether such user approves, agrees, “likes,” etc. such content or disapproves, disagrees, or “dislikes” such content. Such voting facilitates the ability of a computer system of the present invention to establish rank-weighting rankings, time-weighting rankings, etc. The Client Computer will preferably permit a user to respond to such votes, on an individualized or global manner, so as to permit a voting user to view additional information (such as the user's name. username, etc.). Thus, for example, a user posting content anonymously may receive a vote of approval from another user, and respond by permitting the approving user to learn the posting user's identity, location, etc. Preferably, such permission may be subsequently augmented or terminated by the posting user.

As indicated above, in one embodiment of the present invention, a Client Computer of the present invention will have the ability to discern or identify the language of received content (e.g., the language used in received text, sound, image (e.g., advertisements, menus, notices, maps, street signs, etc.), video, etc.). Thus, such client computers will have the ability to present content that was received in one or more languages. In a further embodiment, such Client Computers will also have the ability to translate and present such received “first” language content into one, two or more user-selected alternative (or additional) language(s) (collectively referred to as a “second” language), so as to be able to receive content that was in such “first” language and present it to that user in such “second” language. By adjusting a user's preferences, such a Client Computer can present such content exclusively in such “first” language, exclusively in such “second” language, or in both such “first” language and such “second” language (for example, in bilingual regions, such as Quebec, or trilingual regions such as India). Such first or second languages may, for example, be Chinese, Spanish, English, Hindi, Arabic, Portuguese, Bengali, Urdu, Russian, Japanese, Punjabi/Lahnda, French, German, Korean, etc. In one embodiment, such translation and presentation will be accomplished upon the direction of individual users (through each such user's language user preference or weighting preferences), so as, for example, to allow a user to access presented local content in that user's native language. Thus, for example, an advertisement in a first language would be translated into a second language at a user's direction in order to permit such user to review the content in the user's preferred language. In a second embodiment, such translation and presentation will be accomplished upon the direction of the network (subject to a user's language user preference or weighting preferences), so as, for example, to allow content that was prepared in one language to be automatically and initially translated into a second language and provided to such users who are within a geographic area known to have a high level of individuals for whom such second language is their native language. Thus, for example, an advertisement in a first language would be translated into differing second language(s) at the network's direction in order to permit such content to be more widely appreciated by users in geographical areas that are associated with users of differing preferred language(s).

The ability of a Client Computer to translate such content and present such translations may be accomplished using, for example: an internal language translation program (that may use, for example, an internal statistical machine translation technology (SMT) or a hybrid neural machine translation (NMT) technology), or a third-party translation or dictionary program (for example, Apertium, Babylon, Power Translator, Prompt, Personal Translator, Systran, IdiomaX, Cute Translator, Word Magic, NeuroTran, etc.), or by permitting a user's Client Computer to access a publicly available translation site or capability (for example, Babelfish.com®, Cucumis, Flitto, Google Translate, Khandbahale.com, Microsoft Translator, Omniscien Technologies, ProZ.com, UniLang, Yandex.Translate, Yeminli etc.). Access to, and use of, such third-party translation program or such publicly available translation site or capability (which may be internet-based, network-based or stored on the Client Computer for offline use) may, for example, be licensed to the Client Computer from the third party through payment of a shared or non-shared user fee.

In a further embodiment, the Client Computers of the present invention may have the ability to discern or identify price and/or pricing information of received content (e.g., price and/or pricing information relating to goods or services in signage, advertisements, notices, menus, etc. of such received content) that is in a “first” currency and to convert and present such received “first” currency content into a user-selected alternative (or additional) “second” currency, so as to be able to receive content that was in such “first” currency and present it to that user in such “second” currency. By adjusting a user's preferences, such a Client Computer can present such content exclusively in such “first” currency, exclusively in such “second” currency, or in both such “first” currency and such “second” currency. Since the relative valuation of currencies varies, such ability of a Client Computer to calculate and present such currency conversions is preferably accomplished using a third-party currency calculation program or a publicly available currency calculation site or capability (for example, XE.com, travelex.com, transferwise.com, ofx.com, etc.). Access to, and use of, such third-party translation program or such publicly available translation site or capability (which may be internet-based, network-based, or updated and stored on the Client Computer) may, for example, be licensed to the Client Computer from the third party through payment of a shared or non-shared user fee.

V. Content-Monitoring Computers and Content Flow Analysis (“Data-Mining”)

In a preferred embodiment, one or more of the computers of a computer system of the present invention will be configured as a “Content-Monitoring” computer. Content Monitoring computers differ from the above-described Client Computers, among other attributes, in being particularly adapted to analyze network content flow relating to one or more particular topics selected by the Content-Monitoring Computer's user or to network-selected segment(s). Content-Monitoring Computers preferably do not automatically drop from their stacks content of lesser value, but retain such content so that time-based variations of content amount or frequency can be provided. Content-Monitoring Computers thus have the ability to monitor the flow of content across the network. Content-Monitoring Computers will preferably have greater processing power and greater memory capacity than other Client Computers. Content-Monitoring Computers may be non-mobile devices, such as desktop computers, servers, etc.

As used herein, the term “Content-Selected Monitoring,” and variants thereof, are intended to denote the ability of a Content-Monitoring Computer to discern Client Computers that are receiving or providing selected content. Preferably, such discernment will be anonymous to the extent that the personal identities (i.e., name, username, etc.) and/or attributes (address, age, credit card information, etc.) of the users of such discerned Client Computers are not conveyed to, or are not stored by, the Content-Monitoring Computer. Significantly, the Content-Monitoring Computer will, however, preferably have the ability to access the user's identifier coding (or the Client Computer's identifier coding). This attribute facilitates the ability of Content-Monitoring Computers to categorize users and the favorable voted-upon content or disseminated content of their Client Computers based on the profile of the Client Computer's user (“user profile”). Whereas some aspects of a user's profile will be non-anonymous (e.g., information required to establish and fund a user's account), other aspects of a user's profile may be discerned by the Content-Monitoring Computer in an anonymous manner (i.e., without correlating such aspects to name, address or other information that would permit others to identify the user). Such anonymous aspects of a user's profile may include the user's age, income level, location and identification (gender, ethnicity, race, locality, etc.). Thus, such Content-Monitoring Computers possess an ability to discern and analyze the union of topics of interest that they access, and to track changes in the recency, magnitude, excitement, or other attribute(s) or characteristic(s) with which such users interact with one another or with particular products. Thus, the computer systems of the present invention may be operated to provide user(s) of Content-Monitoring Computers with the ability to perceive the flow of content across the entire network or any sub-region thereof. In combination with query-weighting content presentation requests, such Content-Monitoring Computers can be used to evaluate the extent to which such selected flow relates to a user-selected attribute (i.e., facilitating “data-mining” of a current content flow). In further combination with a time-weighting content presentation request, and when a log or database of past content has been created, such Content-Monitoring Computers allow their users to access content that flowed across the network at specified time(s) in the past, or in particular locations, or for specified time period duration(s), which can be used to evaluate the extent to which such selected past flow relates to a user-selected attribute (i.e., “data-mining” a past content flow).

Thus, for example, a Content-Monitoring Computer that has been instructed to monitor content relating to a particular service, event, location, product, etc. would be able to discern the percentage of Client Computers on the network that have been instructed to receive or provide content relating to such service, event, location, product, etc. Preferably, the Content-Monitoring Computer would also be capable of accessing such content so as to permit its user to perceive the favorability/disfavorability, ranking, recency, topics etc. pertaining to such content. Thus, for example, a Content-Monitoring Computer instructed to monitor content relevant to a selected product (e.g., a fast food product, a television, etc.) or a selected event (e.g., individuals entering an office building, attending a fair, or visiting a museum) would be able to discern, typically anonymously, how many users are commenting about the product or event (in absolute number, or in relative to the total number of Client Computers of the network, and the reactions of such users to the selected product. A manufacturer, sponsor, administrator, etc. could then use such information to improve or vary the product or alter the event conditions (e.g., re-allocate sales help, address depleting inventory, address over-crowding, etc.) so as to increase the favorability, etc. of the product or event.

An additional attribute of the present invention is that such Content-Selected Monitoring may be cross-correlated with other content to provide the Content-Monitoring Computer with the ability to discern the demographics of users whose Client Computers have been instructed to receive or provide the selected content and such other content. Thus, for example, a Content-Monitoring Computer may be instructed to monitor content regarding a product (i.e., the selected content). Such content may be presented in response to a language preference indicated by a user. For example, content (including advertising, notices, menus, etc.) may be disseminated in a particular language in order to target users who have indicated a weighting preference to be presented with content in that language. Thus, for example, the invention permits directed content provision (including targeted advertising) to a group of users sharing a language demographic that may be relevant to the content originator (e.g., governmental entity, commercial entity, organization, etc.). Similarly, the invention, through its capability to translate content from a first language into a second language permits content provision (including advertising) to be more easily accessed and used by users sharing a different language demographic from that used by the content originator.

Such additional content may be query-specified, and/or may involve one, two or multiple topics. The Content-Monitoring Computer may then also be instructed to monitor content regarding a particular service, event or location. By then instructing the Content-Monitoring Computer to compare the identifier codings associated with Client Computers receiving or providing both such contents, the Content-Monitoring Computer can discern the number and relative percentage of the intersection of Client Computers that are receiving or providing content about both the relevant product and such particular service, event or location. As an example, by selecting to monitor “Apple® computer” and then cross-correlating with a proximity of “North Carolina” or “California,” one can discern the number or percentage of Client Computers concerned with Apple® computers in North Carolina or California. By performing such selection repeatedly over time, one can discern how the association varies over time.

The capability of the Content-Monitoring Computers of the present invention thus differs significantly from those provided by social reviewing networks such as Yelp® or Angie's List®, in being anonymous, automatic, dynamic, and correlatable.

Although Content-Monitoring Computers are primarily involved in monitoring network content, Content-Monitoring Computers may also have the ability to provide content to Client Computers of the network. For example, a Content-Monitoring Computer may respond to the monitored content flow by providing inducements to other Client Computers (e.g., coupons, free additional content, etc.) to motivate users to comment more favorably about a service, event, location, product, etc. Similarly, the operators of the amusement park could use a Content-Monitoring Computer to provide Client Computers with information about less crowded areas of the park in order to direct park guests away from more congested park areas.

VI. Exemplary User Interfaces of the Client Computers of the Computer Systems of the Present Invention

The Client Computers of the present invention will preferably present to its user a graphical user interface that will comprise text input boxes sufficient to permit a user to indicate the user's profile and/or preferences in accessing and using a computer system of the present invention. Such profile and preferences may include, the user's actual name, a selected “username,” a selected password, preferences relating to the desired type or types of weighting, and the parameter(s) of such weighting (e.g., the time interval to be used in time-weighting, the distance parameter to be used in proximity-weighting, etc.). Such a text input screen is shown in FIG. 5. Additionally, such preferences may include a user's privacy preferences, such as whether the user's actual name (or selected username, emoji (see, e.g., U.S. Pat. Nos. 10,025,972; 9,794,202; 9,699,299; and 9,665,567), or avatar) is to be viewable by other users, or whether such user's content is to be anonymous to other users. The privacy preferences may additionally restrict the distribution of a user's content to one or more user-selected other users (“friends”).

Any of a wide variety of user interfaces may be employed to permit the user to effectively perceive received content or provide content to other users. Such interfaces may be textual, such as a thread list, but more preferably, an “atomic” user interface is employed, in which the user by “grasping” one or more graphical elements (or selecting such graphical elements) (FIG. 6) of a touch-sensitive, or voice-responsive, screen is able to have the interface “zoom in” to see one or more previously smaller or previously-non-visible graphical elements, denoting a smaller universe of more selected content. Conversely, by “pinching” one or more of the graphical elements (or selecting such graphical elements), the user is able to have the interface “zoom out” to present additional content topics (FIG. 7). Preferably, the interface will permit the user to swipe across the graphical elements to cause them to revolve and thereby bring additional graphic elements into view. The graphical element(s) are preferably sized, colored, labeled, and/or textured, etc. to indicate their relative weighting, such that, for example, if time-weighting is applied, the graphical element associated with a topic of greater recency will be more prominently colored or displayed, etc. It is also preferred that the graphical element(s) are sized, colored, labeled, and/or textured, etc. to indicate the rate of change of a topic relative to such weighting. For example, the graphical elements may be spheres whose diameter reflects the weighting of the content, and whose color reflects the rate of change of that topic relative to such weighting. Alternatively, the thickness of the circular outer boundary of such spheres may vary in proportion to the rate of change of that topic relative to such weighting.

The interface will additionally preferably permit the user to drag graphical element(s), so that graphical elements representing topics having a user-perceived or user-defined relationship may be adjacent to one another or spaced relative to one another in a manner desired by the user. FIG. 8 illustrates the invention by showing how such zooming may be used to ultimately lead to the presentation of content, and shows an illustrative topic conversation among several attendees of a lecture. Initially the participants are commenting anonymously, however, “Anon28” and “Anon12” eventually reveal their identities to one another. As shown in FIG. 8, users may elect to provide textual content, image content or sound content.

Preferably, the user interface will permit the user to drag graphic elements to be placed onto a sorting graphic element (FIG. 9A) or to overlap with one another (FIG. 9B) so as to permit the user to view related content that relates to two or more topics. Still more preferably, the user interface will permit the user to select graphic elements (which may then change color, or appearance to indicate such selection), to thereby select to view related content that relates to the topics of the selected graphical elements (FIG. 9C). Thus, the graphical element labeled “Seattle,” as shown in FIGS. 9A-9C, includes multiple topics all of which relate in some manner to Seattle, and the graphical element labeled “Weather,” in FIGS. 9A-9C includes multiple topics all of which relate in some manner to weather anywhere. However, by dragging the “Seattle” and “Weather” graphical elements to a sorting graphical element (shown as a star) a user may select to view content involving the weather in Seattle (FIG. 9A). Alternatively, a user may drag one graphic element (e.g., the “Seattle” graphical element) so that it overlaps with another graphic element (e.g., the “Weather” graphical element) to access content relating to weather in Seattle (FIG. 9B). Alternatively, the user may “select” the graphical elements of interest (e.g., by touching such graphical elements). The interface then preferably alters the appearance of the selected elements to indicate their selection, and provides the user with content relating to topics involving the selected graphical elements (e.g., Seattle weather; FIG. 9C).

Particularly in conjunction with location-weighting, the user interface may comprise a map (such as a “heat map”) having graphical element(s) that are sized, colored, labeled, and/or textured, etc. to indicate their relative weighting. The weighting content of such a heat map may optionally be superimposed upon geographic data (e.g., the locations of buildings or other structures, waterways, land elevation or slope contours, the nature of terrain (wooded, rocky, mountainous, open field, etc.). Thus, for example, a Client Computer presenting a time-weighting map of an amusement park would present its user with a gradient of the currently most crowded areas of the park. FIG. 10A illustrates this aspect of the present invention, showing Town Square and Future Land as being the most crowded sections of an amusement park. A user might then elect to visit other, less crowded areas of the park. The user might then direct his/her Client Computer to present a rank-weighting map of the amusement park, and thus be able to perceive a gradient of the areas of the park currently spurring the most discussion. FIG. 10B illustrates this aspect of the present invention, showing that something interesting is happening in the Magic Land and Adventure Place sections of the park. The operators of the amusement park could use a Content-Monitoring Computer to assess how such “heat maps” of park traffic are changing over time, and thus be able to better allocate park resources so as to alleviate congestion or foster improved traffic flow. Preferably, such heat map changes are provided to the user of the Content-Monitoring Computer in real time (e.g., as a pseudo-video formed from rapidly updating static heat map images, or as a continuous video of traffic flow, etc.).

Particularly in conjunction with geophysically-weighting and location-weighting, the user interface may comprise a map (such as a “heat map”) having graphical element(s) that are sized, colored, labeled, and/or textured, etc. capable of indicating the number and position of users who may be stranded in the path of an oncoming storm, fire, or other geophysical event, thus facilitating rescue or evacuation. The location weighting permits the map to additionally show the movement (i.e., change in position) of such stranded users.

The user interface may exploit a camera or other optical image input, if such is present on the Client Computer device. For example, the user interface may use the camera of a camera-containing Client Computer to associate content with a particular location, orientation or user. Thus, the user interface will appear to be an image of the surroundings (for example, an augmented reality image) that comprises one or more annotations relating to the location or orientation of a content provider and the nature of the provided content (FIG. 11). Client computers of users that have provided permission to a receiving Client Computer may be specifically localized on the user interface, so as to be personally identified. Conversely, Client Computers of users that have not granted such permission will preferably be localized only to an area, so as to remain anonymous to the receiving Client Computer.

The user interface will preferably notate users having multiple approving votes with a symbol (e.g., a star, thumbs up, etc.) denoting such approval. The user interface may additionally notate users having multiple disapproving votes with a symbol denoting such disapproval.

All publications and patents mentioned in this specification are herein incorporated by reference to the same extent as if each individual publication or patent application was specifically and individually indicated to be incorporated by reference in its entirety. While the invention has been described in connection with specific embodiments thereof, it will be understood that it is capable of further modifications and this application is intended to cover any variations, uses, or adaptations of the invention following, in general, the principles of the invention and including such departures from the present disclosure as come within known or customary practice within the art to which the invention pertains and as may be applied to the essential features hereinbefore set forth. 

What is claimed is:
 1. A computer system for disseminating content among interconnected Client Computers, wherein said computer system comprises: a content-providing Client Computer (I) and a content-receiving Client Computer (II), interconnected, via a digital or an analog connection, with one another directly or through one or more other Client Computer(s) to form a distributed communications network; wherein: (A) one or more of: (1) said content-providing Client Computer (I); (2) said content-receiving Client Computer (II); and/or (3) said other Client Computer(s), if said content-providing Client Computer (I) and said content-receiving Client Computer (II) are interconnected to said distributed communications network via said other Client Computer(s); communicates with an interconnected Client Computer via an infrared signal, a laser pulse, or a radio frequency; (B) said content-providing Client Computer (I) is adapted to transmit data comprising text content, sound content, image content and/or video content, wirelessly or via a wired connection, to said content-receiving Client Computer (II) either directly or through said one or more other Client Computer(s) of said distributed communications network; (C) said content-receiving Client Computer (II) is adapted to receive at least a subset of the transmitted data of said content-providing Client Computer (I); wherein the content of said received or presented content adjusts in response to changes in: (i) a Favorability Value assigned by said content-providing Client Computer (I); and/or (ii) a weighting preference assigned by said content-receiving Client Computer (II); and/or (iii) where said Client Computers (I) and (II) are interconnected to one another through one or more other Client Computer(s), a Favorability Value assigned by one or more of said other Client Computer(s); thereby disseminating content across said distributed network; and wherein said Favorability Value is determined by a Favorability Function that considers one or more Favorability Parameter(s), with the proviso that when selected Favorability Parameters include both vote and time, the Favorability Function shall additionally consider one or more additional Favorability Parameter(s).
 2. The computer system of claim 1, wherein said content-receiving Client Computer (II) of said computer system stores received content in a Content Stack memory; wherein content stored in said Content Stack memory rises in response to increases in Favorability Value of the content, and/or falls in the Content Stack memory in response to decreases in Favorability Value, such that the number or amount of content stored in the Content Stack memory remains within available processing and bandwidth parameters.
 3. The computer system of claim 2, wherein said content-receiving Client Computer (II) of said computer system presents a subset of said stored received content to its user, wherein said presented content is stored in a Presentation Stack memory; wherein content stored in said Presentation Stack memory: (A) rises in the Presentation Stack memory in response to: (1) increased proximity between said content-receiving Client Computer (II) and said content-providing Client Computer (I); (2) increases in the Favorability Value of the content: (i) assigned by said content-providing Client Computer (I); and/or (ii) assigned by said content-receiving Client Computer (II); and/or (iii) where said Client Computers (I) and (II) are interconnected to one another through one or more other Client Computer(s), assigned by one or more of said other Client Computer(s); and/or (3) changes in weighting preferences applied by said content-receiving Client Computer (II) that increase its user's desire for such content; and/or (B) falls in the Presentation Stack memory in response to: (1) decreased proximity between said content-receiving Client Computer (II) and said content-providing Client Computer (I); (2) decreases in the Favorability Value of the content: (i) assigned by said content-providing Client Computer (I); and/or (ii) assigned by said content-receiving Client Computer (II); and/or (iii) where said Client Computers (I) and (II) are interconnected to one another through one or more other Client Computer(s), assigned by one or more of said other Client Computer(s); and/or (3) changes in weighting preferences applied by said content-receiving Client Computer (II) that decrease its user's desire for such content; such that the number or amount of content stored in the Presentation Stack memory of Client Computer (II) remains within user-selected parameters.
 4. The computer system of claim 3, wherein said presented content is weighed based on one or more weighting preference(s) selected from the group consisting of: proximity-weighting, rank-weighting, topic-weighting, query-weighting, time-weighting, location-weighting, locality-weighting, vote-weighting, segment-weighting and geophysical-weighting.
 5. The computer system of claim 1, wherein said one or more of: (1) said content-providing Client Computer (I); (2) said content-receiving Client Computer (II); and/or (3) said other Client Computer(s), if said content-providing Client Computer (I) and said content-receiving Client Computer (II) are interconnected to said distributed communications network via said other Client Computer(s); communicates with an interconnected Client Computer via an infrared signal.
 6. The computer system of claim 5, wherein said one or more of: (1) said content-providing Client Computer (I); (2) said content-receiving Client Computer (II); and/or (3) said other Client Computer(s), if said content-providing Client Computer (I) and said content-receiving Client Computer (II) are interconnected to said distributed communications network via said other Client Computer(s); is mounted in a vehicle, installed in or on a structure or is a component of a drone device and communicates with an interconnected Client Computer.
 7. The computer system of claim 1, wherein said one or more of: (1) said content-providing Client Computer (I); (2) said content-receiving Client Computer (II); and/or (3) said other Client Computer(s), if said content-providing Client Computer (I) and said content-receiving Client Computer (II) are interconnected to said distributed communications network via said other Client Computer(s); communicates with an interconnected Client Computer via a laser pulse.
 8. The computer system of claim 7, wherein said one or more of: (1) said content-providing Client Computer (I); (2) said content-receiving Client Computer (II); and/or (3) said other Client Computer(s), if said content-providing Client Computer (I) and said content-receiving Client Computer (II) are interconnected to said distributed communications network via said other Client Computer(s); is mounted in a vehicle, installed in or on a structure or is a component of a drone device and communicates with an interconnected Client Computer.
 9. The computer system of claim 1, wherein said one or more of: (1) said content-providing Client Computer (I); (2) said content-receiving Client Computer (II); and/or (3) said other Client Computer(s), if said content-providing Client Computer (I) and said content-receiving Client Computer (II) are interconnected to said distributed communications network via said other Client Computer(s); communicates with an interconnected Client Computer via a radio frequency.
 10. The computer system of claim 9, wherein said one or more of: (1) said content-providing Client Computer (I); (2) said content-receiving Client Computer (II); and/or (3) said other Client Computer(s), if said content-providing Client Computer (I) and said content-receiving Client Computer (II) are interconnected to said distributed communications network via said other Client Computer(s); is mounted in a vehicle, installed in or on a structure or is a component of a drone device and communicates with an interconnected Client Computer.
 11. The computer system of claim 1, wherein said network additionally comprises a Content-Monitoring Computer.
 12. The computer system of claim 1, wherein said network comprises a Restricted Computer Network.
 13. The computer system of claim 1, wherein said content-receiving Client Computer (II) presents received content to a user using a graphical user interface.
 14. The computer system of claim 1, wherein said content-providing Client Computer (I) is additionally adapted to receive at least a subset of text content, sound content, image content and/or video content transmitted from another Client Computer, and wherein at least a subset of said content received by said content-receiving Client Computer (II) directly or indirectly from said content-providing Client Computer (I), and presented to the user of said content-receiving Client Computer (II), was received by said content-providing Client Computer (I) from said other Client Computer.
 15. The computer system of claim 1, wherein said content-receiving Client Computer (II) is additionally adapted to transmit data comprising text content, sound content, image content and/or video content, wirelessly or via a wired connection, to another Client Computer either directly or through said one or more other Client Computer(s) of said distributed communications network.
 16. A computer-implemented method for disseminating content among interconnected Client Computers, wherein said method enables the interconnection, via a digital or an analog connection, of a content-providing Client Computer (I) and a content-receiving Client Computer (II), directly or through one or more other Client Computer(s), to thereby form a distributed communications network, wherein: (A) one or more of: (1) said content-providing Client Computer (I); (2) said content-receiving Client Computer (II); and/or (3) said other Client Computer(s), if said content-providing Client Computer (I) and said content-receiving Client Computer (II) are interconnected to said distributed communications network via said other Client Computer(s); communicates with an interconnected Client Computer via an infrared signal, a laser pulse, or a radio frequency; (B) said content-providing Client Computer (I) transmits data comprising text content, sound content, image content and/or video content, wirelessly or via a wired connection, to said content-receiving Client Computer (II) either directly or through said one or more other Client Computer(s) of said distributed communications network; and (C) said content-receiving Client Computer (II) receives at least a subset of the transmitted data of said content-providing Client Computer (I); wherein the content of said received or presented data adjusts in response to changes in: (i) a Favorability Value assigned by said content-providing Client Computer (I); and/or (ii) a weighting preference assigned by said content-receiving Client Computer (II); and/or (iii) where said Client Computers (I) and (II) are interconnected to one another through one or more other Client Computer(s), a Favorability Value assigned by one or more of said other Client Computer(s); thereby disseminating content across said distributed network; and wherein said Favorability Value is determined by a Favorability Function that considers one or more Favorability Parameter(s), with the proviso that when selected Favorability Parameters include both vote and time, the Favorability Function shall additionally consider one or more additional Favorability Parameter(s).
 17. The computer-implemented method of claim 16, wherein said method permits said content-receiving Client Computer (II) of said computer system to store received content in a Content Stack memory; wherein said method permits content stored in said Content Stack memory to rise in response to increases in Favorability Value of the content, and/or to fall in the Content Stack memory in response to decreases in Favorability Value, such that the number or amount of content stored in the Content Stack memory remains within available processing and bandwidth parameters.
 18. The computer-implemented method of claim 16, wherein said method permits said content-receiving Client Computer (II) of said computer system to present a subset of said stored content to its user, wherein said presented content is stored in a Presentation Stack memory; wherein said method permits content stored in said Presentation Stack memory: (A) to rise in the Presentation Stack memory in response to: (1) increased proximity between said content-receiving Client Computer (II) and said content-providing Client Computer (I); (2) increases in the Favorability Value of the content: (i) assigned by said content-providing Client Computer (I); and/or (ii) assigned by said content-receiving Client Computer (II); and/or (iii) where said Client Computers (I) and (II) are interconnected to one another through one or more other Client Computer(s), assigned by one or more of said other Client Computer(s); and/or (3) changes in the weighting preferences applied by said content-receiving Client Computer (II) that increase its user's desire for such content; and/or (B) to fall in the Presentation Stack memory in response to: (1) decreased proximity between said content-receiving Client Computer (II) and said content-providing Client Computer (I); (2) decreases in the Favorability Value of the content: (i) assigned by said content-providing Client Computer (I); and/or (ii) assigned by said content-receiving Client Computer (II); and/or (iii) where said Client Computers (I) and (II) are interconnected to one another through one or more other Client Computer(s), assigned by one or more of said other Client Computer(s); and/or (3) changes in the weighting preferences applied by said content-receiving Client Computer (II) that decrease its user's desire for such content; such that the number or amount of content stored in the Presentation Stack memory of the Client Computer remains within user-selected parameters.
 19. The computer-implemented method of claim 18, wherein said method permits said presented content to be weighted based on one or more weighting preference(s) selected from the group consisting of: proximity-weighting, rank-weighting, topic-weighting, query-weighting, time-weighting, location-weighting, locality-weighting, vote-weighting, segment-weighting, and geophysical-weighting.
 20. The computer-implemented method of claim 16, wherein said one or more of: (1) said content-providing Client Computer (I); (2) said content-receiving Client Computer (II); and/or (3) said other Client Computer(s), if said content-providing Client Computer (I) and said content-receiving Client Computer (II) are interconnected to said distributed communications network via said other Client Computer(s); communicates with an interconnected Client Computer via an infrared signal.
 21. The computer-implemented method of claim 20, wherein said one or more of: (1) said content-providing Client Computer (I); (2) said content-receiving Client Computer (II); and/or (3) said other Client Computer(s), if said content-providing Client Computer (I) and said content-receiving Client Computer (II) are interconnected to said distributed communications network via said other Client Computer(s); is mounted in a vehicle, installed in or on a structure or is a component of a drone device and communicates with an interconnected Client Computer.
 22. The computer-implemented method of claim 16, wherein said one or more of: (1) said content-providing Client Computer (I); (2) said content-receiving Client Computer (II); and/or (3) said other Client Computer(s), if said content-providing Client Computer (I) and said content-receiving Client Computer (II) are interconnected to said distributed communications network via said other Client Computer(s); communicates with an interconnected Client Computer via a laser pulse.
 23. The computer-implemented method of claim 22, wherein said one or more of: (1) said content-providing Client Computer (I); (2) said content-receiving Client Computer (II); and/or (3) said other Client Computer(s), if said content-providing Client Computer (I) and said content-receiving Client Computer (II) are interconnected to said distributed communications network via said other Client Computer(s); is mounted in a vehicle, installed in or on a structure or is a component of a drone device and communicates with an interconnected Client Computer.
 24. The computer-implemented method of claim 16, wherein said one or more of: (1) said content-providing Client Computer (I); (2) said content-receiving Client Computer (II); and/or (3) said other Client Computer(s), if said content-providing Client Computer (I) and said content-receiving Client Computer (II) are interconnected to said distributed communications network via said other Client Computer(s); communicates with an interconnected Client Computer via a laser pulse.
 25. The computer-implemented method of claim 24, wherein said one or more of: (1) said content-providing Client Computer (I); (2) said content-receiving Client Computer (II); and/or (3) said other Client Computer(s), if said content-providing Client Computer (I) and said content-receiving Client Computer (II) are interconnected to said distributed communications network via said other Client Computer(s); is mounted in a vehicle, installed in or on a structure or is a component of a drone device and communicates with an interconnected Client Computer.
 26. The computer-implemented method of claim 16, wherein said method permits said network to additionally comprise a Content-Monitoring Computer.
 27. The computer-implemented method of claim 16, wherein said method permits said network to comprise a Restricted Computer Network.
 28. The computer-implemented method of claim 16, wherein said content-receiving Client Computer (II) presents said received data to said user using a graphical user interface.
 29. The computer-implemented method of claim 14, wherein said content-providing Client Computer (I) additionally receives at least a subset of text content, sound content, image content and/or video content transmitted from another Client Computer, and wherein at least a subset of said data received by said content-receiving Client Computer (II) directly or indirectly from said content-providing Client Computer (I), and presented to the user of said content-receiving Client Computer (II), was received by said content-providing Client Computer (I) from said other Client Computer.
 30. The computer-implemented method of claim 16 wherein said content-receiving Client Computer (II) additionally transmits data comprising text content, sound content, image content and/or video content, wirelessly or via a wired connection, to another Client Computer either directly or through said one or more other Client Computer(s) of said distributed communications network. 